ADVANCED CARDIAC LIFE

SUPPORT(ACLS) - 2010

Speaker ndash Dr TAREK BELASHHER

Abusetta hospital

ACLS Course

Arrest scenarios

VF

Pulse less VT

A systole

PEA

Pre-arrest scenarios

Tachyarrhythmias

Bradyarrythmias

Ischemia

Stable Angina

Unstable Angina

MI

Stroke

Key Issues in ACLS

Airway

CPR

Defibrillation

Drug therapy

Post-resuscitation management

Special Situations

BLS Key Concepts

Avoid Hyperventilation (Do not ventilate too fast or too

much volume)

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Resume CPR immediately after shock Interruption in

CPR for rhythm check should not exceed 10 seconds

BLS Key Concepts

Chest compression should not be interrupted except for

Shock delivery

Rhythm check

Ventilation (until an advanced airway is inserted)

Do not interrupt CPR

To insert cannula or to give drugs

To listen to the heart or to take BP

Waiting for charging the Defibrillator

To rotate personnel

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

ACLS Course

Arrest scenarios

VF

Pulse less VT

A systole

PEA

Pre-arrest scenarios

Tachyarrhythmias

Bradyarrythmias

Ischemia

Stable Angina

Unstable Angina

MI

Stroke

Key Issues in ACLS

Airway

CPR

Defibrillation

Drug therapy

Post-resuscitation management

Special Situations

BLS Key Concepts

Avoid Hyperventilation (Do not ventilate too fast or too

much volume)

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Resume CPR immediately after shock Interruption in

CPR for rhythm check should not exceed 10 seconds

BLS Key Concepts

Chest compression should not be interrupted except for

Shock delivery

Rhythm check

Ventilation (until an advanced airway is inserted)

Do not interrupt CPR

To insert cannula or to give drugs

To listen to the heart or to take BP

Waiting for charging the Defibrillator

To rotate personnel

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Key Issues in ACLS

Airway

CPR

Defibrillation

Drug therapy

Post-resuscitation management

Special Situations

BLS Key Concepts

Avoid Hyperventilation (Do not ventilate too fast or too

much volume)

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Resume CPR immediately after shock Interruption in

CPR for rhythm check should not exceed 10 seconds

BLS Key Concepts

Chest compression should not be interrupted except for

Shock delivery

Rhythm check

Ventilation (until an advanced airway is inserted)

Do not interrupt CPR

To insert cannula or to give drugs

To listen to the heart or to take BP

Waiting for charging the Defibrillator

To rotate personnel

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

BLS Key Concepts

Avoid Hyperventilation (Do not ventilate too fast or too

much volume)

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Resume CPR immediately after shock Interruption in

CPR for rhythm check should not exceed 10 seconds

BLS Key Concepts

Chest compression should not be interrupted except for

Shock delivery

Rhythm check

Ventilation (until an advanced airway is inserted)

Do not interrupt CPR

To insert cannula or to give drugs

To listen to the heart or to take BP

Waiting for charging the Defibrillator

To rotate personnel

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

BLS Key Concepts

Chest compression should not be interrupted except for

Shock delivery

Rhythm check

Ventilation (until an advanced airway is inserted)

Do not interrupt CPR

To insert cannula or to give drugs

To listen to the heart or to take BP

Waiting for charging the Defibrillator

To rotate personnel

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Chances of survival with time

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

ADVANCED CARDIAC LIFE SUPPORT

ACLS impacts multiple key links in the chain of

survival that include interventions to prevent cardiac

arrest treat cardiac arrest and improve outcomes

of patients who achieve return of spontaneous

circulation (ROSC) after cardiac arrest

Interventions aimed at preventing cardiac arrest

include airway management ventilation support

and treatment of bradyarrhythmias and

tachyarrhythmias

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

AHA ADULT CHAIN OF SURVIVAL

1 Immediate recognition of cardiac arrest and

activation of the emergency response system

2 Early CPR with an emphasis on chest

compressions

3 Rapid defibrillation

4 Effective advanced life support

5 Integrated postndashcardiac arrest care

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

CARDIOPULMONARY RESUSCITATION (CPR)

Cardiopulmonary resuscitation (CPR) is a series of

life saving actions that improve the chance of

survival following cardiac arrest

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

KEY CHANGES FROM THE

2005 BLS GUIDELINES

Immediate recognition of SCA based on assessing

unresponsiveness and absence of normal breathing

ldquoLook Listen and Feelrdquo removed from the BLS

algorithm

Encouraging Hands-Only (chest compression only)

CPR

Sequence change CAB rather than ABC

Health care providers continue effective chest

compressions CPR until return of spontaneous

circulation or termination of resuscitative efforts

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

A CHANGE FROM A-B-C TO C-A-B

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

o 2010 (New) ldquoLook listen and feelrdquo was removed from the CPR sequence After delivery of 30 compressions the lone rescuer opens the victimrsquos airway and delivers 2 breaths

2005 (Old) ldquoLook listen and feelrdquo was used to assess breathing after the airway was opened

2010 (New) Initiate chest compressions before ventilations

2005 (Old) The sequence of adult CPR began with opening of the airway checking for normal breathing and then delivery of 2 rescue breaths followed by cycles of 30 chest compressions and 2 breaths

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

2010 (New) It is reasonable for lay rescuers and

healthcare providers to perform chest

compressions at a rate of at least100min

2005 (Old) Compress at a rate of about 100mi

2010 (New) The adult sternum should be

depressed at least 2 inches (5 cm)

2005 (Old) The adult sternum should be depressed

approximately 1 to 2 inches (approximately 4 to 5

cm)n

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

2005 (Old) Cricoid pressure should be used only if

the victim is deeply unconscious and it usually

requires a third rescuer not involved in rescue

breaths or compressions

2010(new)routine use of cricoid pressure in

cardiac arrest is not recommended

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

17

CRICOID PRESSURE

ThyroidCartilage

Cricoid

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

2005 TO 2010 CHANGES

Component of CPR 2005 ECC recommendations

2010 ECC Recommendations

DEPTH OF COMPRESSION

1 frac12 - 2 inches Greater than 2 inches

RATE 100 MINUTE At least 100 MIN

VENTILATION 8-10 MINUTE 8-10 MINUTE

CHEST RECOIL 100 100

INTURUPTIONS Minimized Less than 10 seconds goal

PULSE CHECK HCP Only HCP only Checking for ldquoDEFNITE pulserdquo

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

2010 (New) The precordial thump should not be

used for un witnessed out-of-hospital cardiac arrest

The precordial thump may be considered for

patients with witnessed monitored unstable VT

(including pulse less VT) if a defibrillator is not

immediately ready for use but it should not delay

CPR and shock delivery

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

SUMMARY OF KEY ISSUES AND MAJOR CHANGES

The major changes in advanced cardiovascular life support

(ACLS) for 2010 include the following

bull Quantitative waveform capnography is recommended for

confirmation and monitoring of endotracheal tube placement

and CPR quality

bull The traditional cardiac arrest algorithm was simplified and an

alternative conceptual design was created to emphasize the

importance of high-quality CPR

bull There is an increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

bull Atropine is no longer recommended for routine use in the

management of pulse less electrical activity (PEA)asystole

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

CAPNOGRAPHY RECOMMENDATION

2010 (New) Continuous quantitative waveform

capnography is now recommended for intubated

patients throughout the per arrest period When

quantitative waveform capnography is used for

adults applications now include recommendations

for confirming tracheal tube placement and for

monitoring CPR quality and detecting ROSC based

on end-tidal carbon dioxide (PETCO2) values

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

PROGNOSTIC INDICATORS IN THE ADULT POSTARREST

PATIENT TREATED WITH THERAPEUTIC HYPOTHERMIA

2010 (New) In adult postndashcardiac arrest patients

treated with therapeutic hypothermia it is

recommended that clinical neurologic signs

electrophysiologic studies biomarkers and imaging

be performed where available at 3 days after

cardiac arrest

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Hypothermia

ILCOR Advisory statement (2003)

Unconscious adult patients with spontaneous

circulation after out-of-hospital cardiac arrest

should be cooled to 32-34degC for 12-24 hrs when the

initial rhythm was ventricular fibrillation (VF)

Such cooling may also be beneficial for other

rhythms or in-hospital cardiac arrests

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Hypothermia

Cooling

Retard enzymatic suppress production of free

radicals

Reduction of O2 demand in low-flow regions

Protection of membrane fluidity

Reduction of intracellular acidosis

Decrease in cerebral edema and ICP

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

2010 (New) Advanced life support training

should include training in teamwork

Why Resuscitation skills are often performed

simultaneously and healthcare providers must be

able to work collaboratively to minimize

interruptions in chest compressions Teamwork and

leadership skills continue to be important

particularly for advanced courses that include ACLS

and PALS providers

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

MONITORING DURING CPR

Physiologic parameters

Monitoring of PETCO2 (35 to 40 mmHg)

Coronary perfusion pressure (CPP) (15mmHg)

Central venous oxygen saturation (ScvO2)

Abrupt increase in any of these parameters is a

sensitive indicator of ROSC that can be monitored

without interrupting chest compressions

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Quantitative waveform capnography

If Petco2 lt10 mm Hg attempt to improve CPR

quality

Intra-arterial pressure

If diastolic pressure lt20 mm Hg attempt to improve

CPR quality

If ScvO2 is lt 30 consider trying to improve the

quality of CPR

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

HIGH QUALITY CPR

Chest compressions of adequate rate 100min

A compression depth of at least 2 inches (5 cm) in

adults and in children a compression depth of at

least 15 inches [4 cm] in infants

Complete chest recoil after each compression

Minimizing interruptions in chest compressions

Avoiding excessive ventilation

If multiple rescuers are available rotate the task of

compressions every 2 minutes

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

SOME THINGS REMAIN IMPORTANT

RATE

DEPTH

RELEASE

UNINTERRUPTED

DECREASED VENTILATION

5 KEY

ASPECTS

OF

GOOD

CPR

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

CHEST COMPRESSIONS

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

CHEST COMPRESSIONS

Chest compressions consist of forceful rhythmic

applications of pressure over the lower half of the

sternum

Technique

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

DECOMPRESSION PHASE

back

Maintain contact with the skin at your fingertips while

you lift the heel of your hand off the chest This will

assure that the chest wall recoils completely after

each compression and maximizes the formation of the

vacuum that promotes filling of the heart

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

COMPRESSION RATE (AT LEAST 100

MINUTE)

Rate per minute is NOT a function of ldquospeedrdquo of compressions only but a function of both speed ands minimizing no-flow periods (discussed later) for a total compressionsminute

Compressions rates as high as 130 resulted in favorable outcomes

Compression rates lt87minute saw rapid drop off in ROSC

NEW RECOMMENDATION At LEAST100minute

Better too fast than too slow

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

COMPRESSION DEPTH (AT LEAST 2

INCHES)

Previous studies show that only about 27 of

compressions were deep enough (Wik 2005)

0 (none) were too deep

NEW GIUDELINES The adult sternum should be

depressed at least 2 inches (5 cm) with chest

compression and chest recoilrelaxation times

approximately equal

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

COMPRESSION RATEhellip

Percent segments

within 10 cpm

of AHA Guidelines

31

369

Abella et al 2005 Circulation

76

75

58

42

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

COMPLETE RELEASERECOIL (FULL)

Complete Recoil essential to reduce intrathoracic pressure between compressions

Reducing recoil improves hemodynamic in arrest and improves Coronary Perfusion Pressure (CPP)

Incomplete chest wall recoil can be reduced during CPR by using electronic recording devices that provide real-time feedback

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

ACTIVE COMPRESSION-DECOMPRESSION

CPR (ACD-CPR)

Small studies showed

improvement but a

Cochrane Meta- review of

over 1000 patients did

not

ACD-CPR may be

considered for use when

providers are adequately

trained and monitored

(Class IIb LOE B)

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

MECHANICAL PISTON DEVICES

LUCAS THUMPER ETC

In 3 Studies the use of a mechanical piston device for CPR improved end-tidal CO2 and mean arterial pressure during adult cardiac arrest resuscitation

No long term benefit over manual CPR discovered (yet)

There is insufficient evidence to support or refute the routine use of mechanical piston devices in the treatment of cardiac arrest

Use of such devices during specific cercumstances when manual CPR is difficult may be done (Class IIb LOE C)

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

INTURRUPTIONS

Pausing for procedures

intubation IV pulse check etc)

Pausing for rhythm analysis

Pausing to charge clear and shock

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

KEY POINT

ldquohellipHigh-quality CPR is important not only at the onset but throughout the course of resuscitation Defibrillation and advanced care should be interfaced in a way that minimizes any interruptionin CPRrdquo

AHA 2010 Guidelines

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Coronary vessel injury

Diaphragm injury

Hemopericardium

Hemothorax

Interference with ventilation

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

Liver injury

Myocardial injury

Pneumothorax

Rib fractures

Spleen injury

Sternal fracture

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

AIRWAY

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

AIRWAY AND VENTILATIONS

Opening airway ndash Head tilt chin lift or jaw thrust

The untrained rescuer will provide Hands-Only

(compression-only) CPR

The Health care provider should open the airway

and give rescue breaths with chest compressions

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

AIRWAY Assess the airway ensuring it is

- open

- clear

Jaw thrust can be used

Look in mouth for obstruction teeth tongue vomit

foreign object

Ensure airway is clear

If airway obstructed with fluid (vomit or blood) roll patient onto their side amp clear airway or use suction if available

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

AIRWAY

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

RESCUE BREATHS

By mouth-to-mouth or bag-mask

Deliver each rescue breath over 1 second

Give a sufficient tidal volume to produce visible

chest rise

Use a compression to ventilation ratio of 30 chest

compressions to 2 ventilations

After advanced airway is placed rescue breaths

given asynchronus with compression

1 breath every 6 to 8 seconds (about 8 to 10

breaths per minute)

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

OPEN AIRWAY

Head tilt chin lift + jaw thrust

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

55

OPENING THE AIRWAY

Jaw thrust Head tiltndashchin lift

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

56

THE OROPHARYNGEAL AIRWAY

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

57

MALPOSITION OF

OROPHARYNGEAL AIRWAY

Too short

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

MOUTH TO POCKET MASK

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

60

POCKET-MASK DEVICES

1-way valve

Port to attach O2

source

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

61

MOUTH-TO-MASK VENTILATION

Fingers jaw thrust upward Fingers head tiltndashchin lift

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

62

BAG-MASK VENTILATION

Keymdashventilation volume ldquoenough to produce obvious chest riserdquo

1-Person difficult less effective

2-Personeasier more effective

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

BAGVALVEMASK

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

64

EQUIPMENT FOR INTUBATION

Laryngoscope with several blades

Tracheal tubes

Malleable stylet

10-mL syringe

Magill forceps

Water-soluble lubricant

Suction unit catheters and tubing

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

65

CURVED BLADE ATTACHES TO

LARYNGOSCOPE HANDLE

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

66

CURVED BLADE ATTACHED TO

LARYNGOSCOPE HANDLE

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

67

STRAIGHT-BLADE LARYNGOSCOPE

INSERTED PAST EPIGLOTTIS

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

68

ALIGNING AXES OF UPPER AIRWAY

Extend-the-head-on-neck (ldquolook uprdquo) aligns axis A relative to B

Flex-the-neck-on-shoulders (ldquolook downrdquo) aligns axis B relative

to C

C

ABA

B

C

TracheaPharynx

Mouth

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

SECURING THE AIRWAY

Perform chest compressions with a 302 compression to ventilation ratio

back

The head tilt-chin lift with a good

2-handed face mask seal will

provide adequate ventilations in

most cases Do not delay or

interrupt compressions early in

CPR for a secure airway

CPR AND RESCUE BREATHING

WITH A BAG-VALVE MASK (BVM)

1

When squeezing the bag use one hand and only bring the fingertips

together

DO NOT increase volume

back

RESCUE BREATHING AFTER INTUBATION

DO NOT pause chest compressions to deliver breaths after tube placement

back

72

ESOPHAGEAL-TRACHEAL COMBITUBE

A = esophageal obturator ventilation into trachea through side openings = B

C = tracheal tube ventilation through open end if proximal end inserted in

trachea

D = pharyngeal cuff inflated through catheter = E

F = esophageal cuff inflated through catheter = G

H = teeth marker blindly insert Combitube until marker is at level of teeth

Distal End

Proximal End

B

C

D

E

F

G

H

A

COMBITUBE

74

ESOPHAGEAL-TRACHEAL COMBITUBE INSERTED IN

ESOPHAGUS

A = esophageal obturator ventilation into

trachea through side openings = B

D = pharyngeal cuff (inflated)

F = inflated esophagealtracheal cuff

H = teeth markers insert until marker lines

at level of teeth

D

A

D

B F

H

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

RESCUE BREATHING AFTER INTUBATION

DO NOT pause chest compressions to deliver breaths after tube placement

back

72

ESOPHAGEAL-TRACHEAL COMBITUBE

A = esophageal obturator ventilation into trachea through side openings = B

C = tracheal tube ventilation through open end if proximal end inserted in

trachea

D = pharyngeal cuff inflated through catheter = E

F = esophageal cuff inflated through catheter = G

H = teeth marker blindly insert Combitube until marker is at level of teeth

Distal End

Proximal End

B

C

D

E

F

G

H

A

COMBITUBE

74

ESOPHAGEAL-TRACHEAL COMBITUBE INSERTED IN

ESOPHAGUS

A = esophageal obturator ventilation into

trachea through side openings = B

D = pharyngeal cuff (inflated)

F = inflated esophagealtracheal cuff

H = teeth markers insert until marker lines

at level of teeth

D

A

D

B F

H

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

72

ESOPHAGEAL-TRACHEAL COMBITUBE

A = esophageal obturator ventilation into trachea through side openings = B

C = tracheal tube ventilation through open end if proximal end inserted in

trachea

D = pharyngeal cuff inflated through catheter = E

F = esophageal cuff inflated through catheter = G

H = teeth marker blindly insert Combitube until marker is at level of teeth

Distal End

Proximal End

B

C

D

E

F

G

H

A

COMBITUBE

74

ESOPHAGEAL-TRACHEAL COMBITUBE INSERTED IN

ESOPHAGUS

A = esophageal obturator ventilation into

trachea through side openings = B

D = pharyngeal cuff (inflated)

F = inflated esophagealtracheal cuff

H = teeth markers insert until marker lines

at level of teeth

D

A

D

B F

H

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

COMBITUBE

74

ESOPHAGEAL-TRACHEAL COMBITUBE INSERTED IN

ESOPHAGUS

A = esophageal obturator ventilation into

trachea through side openings = B

D = pharyngeal cuff (inflated)

F = inflated esophagealtracheal cuff

H = teeth markers insert until marker lines

at level of teeth

D

A

D

B F

H

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

74

ESOPHAGEAL-TRACHEAL COMBITUBE INSERTED IN

ESOPHAGUS

A = esophageal obturator ventilation into

trachea through side openings = B

D = pharyngeal cuff (inflated)

F = inflated esophagealtracheal cuff

H = teeth markers insert until marker lines

at level of teeth

D

A

D

B F

H

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Advanced Airways

Once advanced airway in place donrsquot interrupt chest compression for

ventilation and avoid over ventilation 8-10 breathsm

Endotracheal Tube

Laryngeal Mask Airway

LMA

Combitube

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

LARYNGEAL MASK AIRWAY

LMA

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

77

LARYNGEAL MASK AIRWAY (LMA)

The LMA is an adjunctive airway that consists

of a tube with a cuffed mask-like projection at

distal end

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

78

LMA INTRODUCED THROUGH MOUTH INTO

PHARYNX

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

79

LMA IN POSITION

Once the LMA is in position a clear secure airway is present

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

80

ANATOMIC DETAIL

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CRICOID PRESSURE (REALLY)

Cricoid pressure in no arrest patients may offer some measure of protection to the airway from aspiration and gastric insufflation during bag-mask ventilation

However it also may impede ventilation and interfere with placement of a supraglottic airway or intubation

If cricoid pressure is used in special circumstances during cardiac arrest the pressure should be adjusted relaxed or released if it impedes ventilation or advanced airway placement

The routine use of cricoid pressure in cardiac arrest is not recommended

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

FIO2 (DURING ARREST)

Use of 100 inspired oxygen (FIO210) as soon as

it becomes available is reasonable during

resuscitation from cardiac arrest

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

FIO2 (POST ARREST)

Increasing Data that hyper-oxia may increase

incidence of poor neurological outcomes and

increased pulmonary injury

Exact FiO2 recommendations have not been

determined

In the post arrest phase if equipment is available

titration of FiO2 to SPO2 04 is recommended

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PASSIVE O2 DELIVERY DURING ARREST

Passive O2 delivery via ETT has been reviewed

In theory because ventilation requirements are lower than normal during cardiac arrest oxygen supplied by passive delivery is likely to be sufficient for several minutes after onset of cardiac arrest with a patent upper airway

The studies involved resulted in improved outcomes but it is unsure what role (if any) passive O2 had

At this time there is insufficient evidence to support the removal of ventilations from CPR performed by ACLS providers

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ETT

There are no studies directly addressing the timing of advanced airway placement and outcome during resuscitation from cardiac arrest

Although insertion of an endotracheal tube can be accomplished during ongoing chest compressions intubation frequently is associated with interruption of compressions for many seconds

Placement of a supraglottic airway is a reasonable alternative to endotracheal intubation and can be done successfully without interrupting chest compressions

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ETT (MORAL OF STORY)

There are two pitfalls of ETT placement

1- Interruption of CPR

2- Poor Placement practices

Therefore Place during CPR if possible and

optimize first attempt (bougie etc)

If you CANT do this then use a supraglottic

airway

If you cant do this perhaps you should not be a

paramedic Hmmmmmmhelliphellip

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

87

CONFIRMATION

TRACHEAL TUBE PLACEMENT

End-tidal colorimetric CO2 indicators

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

COMPRESSION-VENTILATION RATIO

Ventilation rate = 12min

Compression rate = 78min

Large amplitude waves = ventilations

Small amplitude waves = compressions

Each strip records 16 seconds of time

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

REALITY SUCKShellip

Compression Ventilation Ratio 21

47-48 Breaths a minute

47 Nails in a coffin

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PROLONGED VENTILATIONS

1048707Ventilation Duration = 436 seconds breath

1048707Ventilation Rate = 11 breaths minute

1048707 time under Positive Pressure = 80

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

DECREASING VENTILATION

CPR with Advanced Airway 8 ndash 10 breathsminute

Post-resuscitation 10 ndash 12min

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TREATABLE CAUSES OF CARDIAC ARREST

THE HrsquoS AND TrsquoS

Hrsquos Trsquos

Hypoxia Toxins

Hypovolemia Tamponade (cardiac)

Hydrogen ion(acidosis) Tension pneumothorax

Hypo-hyperkalemia Thrombosis pulmonary

Hypothermia Thrombosis coronary

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

HYPOKALEMIA FLAT ST SEGMENTS

See a normal EKGhellip

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

HYPOKALEMIA PROMINENT U WAVES

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

HYPERKALEMIA PEAKED T WAVES

See a normal EKGhellip

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TREATMENT OF HYPERKALEMIA

Antagonize membrane effects of K +

IV Calcium onset 1-2 min duration 30-60 min

Drive K+ into cells

Insulin (remember to give with glucose)

Beta agonists (high dose) ndash like albuterol

Remove K+ from the body

Kayexalate- binds K+ in gut onset 1-2 hours

Diuretics- only work if renal function remains

Hemodialysis- depends on availability

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ELECTRICAL ALTERNANS THE EKG FINDING

OF TAMPONADE

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TREATMENT OF TAMPONADE PERICARDIOCENTESIS

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TENSION PNEUMOTHORAX

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TREATMENT OF TENSION PTX

Oxygen

Insert a large-bore (ie 14-gauge or 16-gauge)

needle into the second intercostal space (above the

third rib) at the midclavicular line

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Arrest Rhythms

Shockable rhythms

VF

Pulseless VT

Non shockable rhythms

PEA

Asystole

Electrical therapies in ACLS

Cardiversion Defibrillation for Tachyarrhythmias

Unsynchronized = defibrillation (Uses higher energy levels and delivers shock immediately)

Synchronized delivers shock at peak of QRS complex (Avoids delivering shock during repolarization)

Pacing for brady arrhythmias

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PRE‐CORDIAL THUMP

bull No prospective studies so far

bull Rationale is to convert mechanical energy to

electrical energy

bull In all successful cases the thump was given

within first 10s

bull More likely to be successful in converting VT to

sinus rhythm

bull Much less likely for VF

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PRE‐CORDIAL THUMP

bull Consider as an option for witnessed sudden

collapse and defibrillator NOT immediately

available

bull Thump may cause deterioration

ndash Rate acceleration of VT

ndash Conversion of VT to VF

ndash Complete Heart Block

ndash A systole

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PRE‐CORDIAL THUMP

bull Only by trained healthcare providers immediately

confirm cardiac arrest

bull Use ulnar edge of tightly clenched fist

bull Deliver a sharp impact to the lower half of the

sternum from a height of 20 cm

bull After that immediately retract the fist

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

DEFIBRILLATION

Defibrillation is defined as termination of VF for at

least 5 seconds following the shock

Early defibrillation remains the cornerstone therapy

for ventricular fibrillation and pulseless ventricular

tachycardia

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Defibrillation Sequence

Turn the AED on

Follow the AED prompts

Resume chest compressions immediately after the shock(minimize interruptions)

Shock Energy

Biphasic Manufacturer recommendation (eg initial dose of 120-200 J) if unknown use maximum available

Second and subsequent doses should be equivalent and higher doses may be considered

Monophasic 360 J

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Defibrillation technique

Defibrillation Sequence

Action Announcements

1 Switch on

2 Place coupling padsgel in correct position

3 Apply paddles

4 Check ECG rhythm and confirm no pulse

5 Select non-synchronized (VF) setting

6 Charge to required energy level Charging

7 Ensure no-one is in contact with anything touching the patient

Stand clear

8 Press paddle buttons simultaneouslyShocking

now

9eturn to ALS algorithm for further steps

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CAUTION IN USE OF AED

Donrsquot apply pads over pacemakers

Donrsquot apply pads over skin patchesmedications

Be cautious around water

NEVER attach to anyone not in cardiac arrest

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

DO I CHECK FOR A PULSE AFTER I

DELIVER A SHOCK

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

1

No stacked shocks

No pulse check after shock

Single shock will be followed by 2

minutes of CPR then pulse check and

re-analyze if necessary

DEFIBRILLATION

These measures reduce ldquono flow timerdquo Why is it

important to reduce the amount of time when

compressions are not performed

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

WHAT NEXT

Commence CPR immediately after delivering

the shock

Use a ratio of 30 compressions to 2 breaths

Follow the voice prompts amp continue CPR until

signs of life return

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

1-SHOCK PROTOCOL VERSUS 3-SHOCK

SEQUENCE

Evidence from 2 well-conducted prepost design

studies suggested significant survival benefit with

the single shock defibrillation protocol compared

with 3-stacked-shock protocols

If 1 shock fails to eliminate VF the incremental

benefit of another shock is low and resumption of

CPR is likely to confer a greater value than another

shock

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CARDIAC ARREST

Cardiac arrest can be caused by 4 rhythms

1 Ventricular fibrillation(VF)

2 Pulseless ventricular tachycardia (VT)

3 Pulseless electric activity (PEA) and

4 Asystole

How to recognise cardiac arrest

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

VF Pulseless VT

Witnessed arrest

2 rescue breaths then

Defibrillate

Unwitnessed arrest

5 cycles of CPR (2 min)

then

Defibrillate

200 Joules for biphasic

machines

360 Joules for monophasic

machines

Single shock (not 3 shocks)

followed by CPR

No gap between chest

compression and shock

delivery

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

VENTRICULAR FIBRILLATION

Fine VF

Coarse VF

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

VENTRICULAR FIBRILLATION

Rate Cannot be determined because there are no

discernible waves or complexes to measure

Rhythm Rapid and chaotic with no pattern or regularity

P waves Not discernible

PR interval Not discernible

QRS duration Not discernible

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

VENTRICULAR TACHYCARDIA

Treat the following as VF

Pulse less monomorphic VT

Pulse less polymorphic VT

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

POLYMORPHIC VENTRICULAR TACHYCARDIA

Rate 150 to 300 beatsmin typically 200 to 250 beatsmin

Rhythm May be regular or irregular

P waves None

PR interval None

QRS 012 sec or more there is a gradual alteration in the

amplitude and direction of the QRS complexes a

typical cycle consists of 5 to 20 QRS complexes

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

MONOMORPHIC VENTRICULAR TACHYCARDIA

Rate 101 to 250 beatsmin

Rhythm Essentially regular

P waves Usually not seen if present they have no set

relationship with the QRS complexes that appear

between them at a rate different from that of the VT

PR interval None

QRS 012 sec or more often difficult to differentiate

between the QRS and the T wave

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

MONOMORPHIC VENTRICULAR TACHYCARDIA

Signs and symptoms associated with VT vary

Sustained VT does not always produce signs of

hemodynamic instability

VT may occur with or without pulses

Treatment is based on signs and symptoms and the

type of VT

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

WHAT IS THIS RHYTHM

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ASYSTOLE PROTOCOL

Check another lead

Is it on paddles

Power on

Check lead and cable connections

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ASYSTOLE (CARDIAC STANDSTILL)

Rate Ventricular usually not discernible but atrial activity may

be seen (ie ldquoP-waverdquo asystole)

Rhythm Ventricular not discernible atrial may be discernible

P waves Usually not discernible

PR interval Not measurable

QRS Absent

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ldquoP-Waverdquo Asystole

Asystole

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

PULSELESS ELECTRICAL ACTIVITY

Pulseless electrical activity exists when organized

electrical activity (other than VT) is present on the

cardiac monitor but the patient is apneic and

pulseless

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 143

THE RESUSCITATION TEAM

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

GOALS OF THE RESUSCITATION TEAM

To re-establish spontaneous circulation and

respiration

To preserve vital organ function during resuscitation

Your responsibility to the patient continues until

patient care is transferred to a team with equal or

greater expertise

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CRITICAL TASKS OF RESUSCITATION

1 Chest compressions

2 Airway management

3 ECG monitoring and defibrillation

4 Vascular access and medication administration

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TEAM LEADER RESPONSIBILITIES

Assesses the patient

Orders emergency care in accordance with protocols

Considers reasons for cardiac arrest

Supervises team members

Evaluates the adequacy of chest compressions

Ensures that the patient receives appropriate oxygen therapy

Evaluates the adequacy of ventilation

Ensures safe and correct defibrillation when it is indicated

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

TEAM LEADER RESPONSIBILITIES

Ensures the correct choice and placement of vascular access

Confirms proper positioning of an advanced airway

Ensures correct drug dose and route of administration

Ensures the safety of all team members

Problem solves

Decides when to terminate resuscitation efforts

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Copyright copy 2012 by Mosby an imprint of Elsevier Inc 148

TEAM MEMBER RESPONSIBILITIES

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

AIRWAY TEAM MEMBER

Manual airway maneuvers

Oral airway

Nasal airway

Oxygen-delivery devices

Bag-mask ventilation

Suctioning

Advanced airway placement

If within scope of practice

Waveform capnography exhaled

carbon dioxide detector and

esophageal detector device

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

CARDIOPULMONARY RESUSCITATION TEAM

MEMBER

The ACLS or BLS team member who is responsible

for CPR must be able to do the following

Properly perform CPR

Provide chest compressions of adequate rate force

and depth in the correct location

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

ELECTROCARDIOGRAPHYDEFIBRILLATION

TEAM MEMBER

Synchronized versus unsynchronized shocks

Pad or paddle placement

Safety precautions

Indications for and complications of transcutaneous

pacing

Problem solving with regard to equipment failure

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

KEY CONCEPTS REVISITEDhellip

Avoid Hyperventilation

Push hard and fast allow complete chest recoil minimal

interruptions

Compress chest depth of 15 to 2 inches at a rate of 100

compressions per minute

Compression to ventilation ratio 302 after advanced

airway no need to interrupt compression

Turing defibrillator onhellip

5 Hs and 5 Tshellip

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

EPINEPHRINE

Indications

Cardiac arrest

VF VT a systole PEA

Symptomatic bradycardia

After atropine alternative to dopamine

Severe hypotension

When atropine and pacing fail hypotension accompanying

bradycardia phosphodiesterase enzyme inhibitors

Anaphylaxis severe allergic reactions

Combine with large fluid volume corticosteroids

antihistamines

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

EPINEPHRINE

Precautions

May increase myocardial ischemia angina and oxygen demand

High doses do not improve survival may be detrimental

Higher doses may be needed for poisondrug induced shock

Dosing

Cardiac arrest 1 mg (110000) IVIO every 3-5 min

High dose up to 02 mgkg for specific drug ODrsquos

Infusion of 2-10 mcgmin

Endotracheal of 2-25 times normal dose

SQIM 03-05 mg

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

VASOPRESSORS

Drug Therapy

Epinephrine IVIO Dose 1 mg every 3-5 minutes

Vasopressin IVIO Dose 40 units can replace first

or second dose of epinephrine

Amiodarone IVIO Dose First dose 300 mg bolus

Second dose 150 mg

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

KEY CHANGES FROM THE 2005 ACLS

GUIDELINES

Continuous quantitative waveform capnography is

recommended

Cardiac arrest algorithms are simplified and

redesigned to emphasize the importance of high

quality CPR

Atropine is no longer recommended for routine use

in the management of pulseless electrical activity

(PEA)asystole

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Increased emphasis on physiologic monitoring to

optimize CPR quality and detect ROSC

Chronotropic drug infusions are recommended as

an alternative to pacing in symptomatic and

unstable bradycardia

Adenosine is recommended as a safe and

potentially effective therapy in the initial

management of stable undifferentiated regular

monomorphic wide-complex tachycardia

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

Synchronised cardioversion - shock delivery that is

timed (synchronized) with the QRS complex

Narrow regular 50 ndash 100 J

Narrow irregular Biphasic ndash 120 ndash 200 J and

Monophasic ndash 200 J

Wide regular ndash 100 J

Wide irregular ndash defibrillation dose

Adenosine 6 mg rapid iv push follow with NS

flush Second dose 12 mg

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

INITIAL OBJECTIVES OF POSTndash CARDIAC

ARREST CARE

Optimize cardiopulmonary function and vital organ

perfusion

After out-of-hospital cardiac arrest transport patient

to an appropriate hospital with a comprehensive

postndashcardiac arrest treatment

Transport the in-hospital postndash cardiac arrest patient

to an appropriate critical-care unit

Try to identify and treat the precipitating causes of the

arrest and prevent recurrent arrest

THANK YOU

THANK YOU