physiology of hemodynamics & picco parameters in detail
TRANSCRIPT
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Physiology of hemodynamics & PiCCO parameters in detail
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Goal of intensive care medicine
Ensuring adequate organ and tissue oxygenation is the main goal in intensive care
medicine:
O2 to the tissues!
Physiology of hemodynamics
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The circulation
heart = the pump
lung = saturation of the blood with oxygen in exchange with carbon dioxid
tissues and organs = sites where the oxygen is transported to by the circulating blood
arterial vessels = transport blood from the lung to the organs, contain oxygen-rich blood
venous vessels = transport blood from the organs to the lungs, contain oxygen-depleted blood
Physiology of hemodynamics
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Principal task of the circulation:supply organs with oxygen-rich blood and nutrition!
others: transport of hormones and drugsregulation of body temperatureimmunologic and blood coagulation functionevacuation of body waste matters
The circulation is determined by pressure (blood pressure) and
flow (cardiac output)
großer Kreislauf
kleiner Kreislauf
capillaries of the lung
pulmonary circulation
pulmonary artery pulmonary
vein
left heart
right heart
body circulation
capillaries of the body (smallest blood vessels)
The circulation
Physiology of hemodynamics
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Cardiac output
Cardiac Output (CO) is an important parameter for the assessment of the circulatory situation is defined as the amount of blood ejected by the heart within 1 minute is the calculation basis for most PiCCO parameters
The CO is determined by several factors:
amount of blood which fills the chambers of the heart (preload)
resistance against which the heart has to eject the blood (afterload)
heart rate (chronotropy)
power of the heart muscle (contractility)
Physiology of hemodynamics
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Systolic (110 - 120 mmHg)
Diastolic (70 - 80 mmHg)
Cardiac Cycle
normal heart rate: 60-90 bpm
Arterial blood pressure and heart rate
Physiology of hemodynamics
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The Heart as a Pump
Blood returns to into the Right Atrium (RA)
passes through the Tricuspid valve and into the Right
Ventricle (RV)
then through the Pulmonary valve into the Pulmonary Artery
(PA) and to the Lungs
Blood returns from the lungs into the Left Atrium (LA) via the
Pulmonary Veins
then down through the Mitral Valve into the Left Ventricle (LV)
Blood is ejected from the Left ventricle through the Aortic Valve
and into the Aorta
RA
RV
PA
LA
LV
Aorta
Physiology of hemodynamics
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Cardiac Output
Preload Contractility Afterload Chronotropy
Determinants of Cardiac Output
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Amount of blood inside the heart
Resistance against which the heart has to pump
Efficacy of the heart muscle
Number of heart beats per minute
Physiology of hemodynamics
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Cardiac Output
Preload Contractility Afterload Chronotropy
Frank-Starling-Mechanism
Influence of preload and contractility on cardiac output
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Physiology of hemodynamics
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SV
Preload
V
V
V
SV
SVSV
Normal contractility
Preload, CO and Frank-Starling-Mechanism
Target AreaVolume Responsive Volume Overloaded
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Physiology of hemodynamics
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V
V
SV
SV
SV
Preload
Poor contractility
Normal contractility
Target AreaVolume Responsive Volume Overloaded
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Preload, CO and Frank-Starling-Mechanism
Physiology of hemodynamics
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V
V
SV
SV
SV
Preload
High contractility
Normal Contractility
Target AreaVolume Responsive Volume Overloaded
Poor contractility
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Preload, CO and Frank-Starling-Mechanism
Physiology of hemodynamics
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Summary and Key Points
• The goal of volume management is the optimization of cardiac output • An increase in preload leads to an increase in cardiac output, within certain
limits. This is explained through the Frank-Starling-Mechanism.
• The measurement of cardiac output does not show where the patient is located on the Frank-Starling curve.
• For optimization of the CO you must have a valid preload measurement.
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Physiology of hemodynamics
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Goal of intensive care medicine
Ensuring adequate organ and tissue oxygenation is the main goal in intensive care
medicine:
O2 to the tissues!
Physiology of hemodynamics
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Processes contributing to cellular oxygen supply
Aim: Optimal Tissue Oxygenation
Pulmonary Gas exchange Macrocirculation Microcirculation Cell function
Direct Control Indirect
Oxygen AbsorptionLungs
Oxygen TransportationBlood
Oxygen DeliveryTissues
Oxygen UtilisationCells / Microchondria
Volume Catecholamines
Oxygen carriers Ventilation
Physiology of hemodynamics
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Central role of the mixed venous oxygen saturation
Determination of Oxygen Delivery and Consumption
Delivery DO2: DO2 = CO x Hb x 1,34 x SaO2
CO: Cardiac OutputHb: HemoglobinSaO2: Arterial Oxygen SaturationSvO2: Mixed Venous Oxygen SaturationDO2: Oxygen DeliveryVO2: Oxygen Consumption
SaO2CO
Hb
Physiology of hemodynamics
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SaO2
S(c)vO2
Consumption VO2: VO2 = CO x Hb x 1,34 x (SaO2 - SvO2)Delivery DO2: DO2 = CO x Hb x 1,34 x SaO2
CO
Hb
Mixed Venous Saturation SvO2
SvO2
CO: Cardiac OutputHb: HemoglobinSaO2: Arterial Oxygen SaturationSvO2: Mixed Venous Oxygen SaturationDO2: Oxygen DeliveryVO2: Oxygen Consumption
Central role of the mixed venous oxygen saturation
Determination of Oxygen Delivery and Consumption
Physiology of hemodynamics
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Oxygen delivery and its influencing factors
DO2 = Hb x 1,34 x SaO2 x CO
Transfusion
• Transfusion CO: Cardiac Output
Hb: Haemoglobin
SaO2: Arterial Oxygen Saturation
CaO2: Arterial Oxygen Content
Physiology of hemodynamics
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DO2 = Hb x 1,34 x SaO2 x CO
Ventilation
• Transfusion• Ventilation
CO: Cardiac Output
Hb: Hemoglobin
SaO2: Arterial Oxygen Saturation
CaO2: Arterial Oxygen Content
Oxygen delivery and its influencing factors
Physiology of hemodynamics
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DO2 = Hb x 1,34 x SaO2 x CO
VolumeCatecholamines
• Transfusion• Ventilation• Volume• Catecholamines
CO: Cardiac Output
Hb: Hemoglobin
SaO2: Arterial Oxygen Saturation
CaO2: Arterial Oxygen Content
Oxygen delivery and its influencing factors
Physiology of hemodynamics
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Assessment of Oxygen Delivery
CO: Cardiac Output; Hb: Hemoglobin; SaO2: Arterial Oxygen Saturation
DO2 = CO x Hb x 1.34 x SaO2
Oxygen AbsorptionLungs
Oxygen TransportBlood
Oxygen DeliveryTissues
Oxygen UtilizationCells / Mitochondria
Supply
SaO2 CO, Hb
Physiology of hemodynamics
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Monitoring the CO, SaO2 and Hb is essential!
Oxygen AbsorptionLungs
Oxygen DeliveryTissues
Oxygen UtilizationCells / Mitochondria
Oxygen TransportBlood
CO: Cardiac Output; Hb: Hemoglobin; SaO2: Arterial Oxygen Saturation
Supply
Assessment of Oxygen Delivery
CO, HbSaO2
Physiology of hemodynamics
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SvO2
SaO2 CO, HbMonitoring the CO, SaO2 and Hb is essential!
VO2 = CO x Hb x 1.34 x (SaO2 – SvO2)
Oxygen UtilizationCells / Mitochondria
Oxygen AbsorptionLungs
Oxygen TransportBlood
Oxygen DeliveryTissues
CO: Cardiac Output; Hb: Hemoglobin; SaO2: Arterial Oxygen Saturation
Supply
Consumption
Assessment of Oxygen Delivery and Consumption
Physiology of hemodynamics
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SvO2
SaO2 CO, Hb
Monitoring CO, SaO2 and Hb is essential
Monitoring the CO, SaO2 and Hb does not give information re O2-consumption!
Oxygen UtilizationCells / Mitochondria
Oxygen AbsorptionLungs
Oxygen TransportBlood
Oxygen DeliveryTissues
CO: Cardiac Output; Hb: Hemoglobin; SaO2: Arterial Oxygen Saturation
Supply
Consumption
Assessment of Oxygen Delivery and Consumption
Physiology of hemodynamics
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Summary and Key Points
• The purpose of the circulation is cellular oxygenation
• For an optimal oxygen supply at the cellular level the macro and micro-circulation have to be balanced along with pulmonary gas exchange
• Next to CO, Hb and SaO2 is SvO2 which plays a central role in the assessment of
oxygen supply and consumption.
• No single parameter provides enough information for a full assessment of oxygen supply at the tissues.
Physiology of hemodynamics
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PiCCO2 - get the complete picture!
Cardiac output Arterial oxygen content
Stroke volume Heart rate OxygenationSaO2
HemoglobineHb
PreloadGEDI; SVV
AfterloadSVRI; MAP
ContractilityCFI
Pulmonary Edema
ELWI
Volume? Vasopressors? Inotropics? Blood transfusion?
Global oxygenationScvO2
Oxygen delivery Oxygen consumption
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SvO2
SaO2 CO, Hb
Monitoring CO, SaO2 and Hb is essential
Monitoring the CO, SaO2 and Hb does not give information re O2-consumption!
Oxygen UtilizationCells / Mitochondria
Oxygen AbsorptionLungs
Oxygen TransportBlood
Oxygen DeliveryTissues
CO: Cardiac Output; Hb: Hemoglobin; SaO2: Arterial Oxygen Saturation
Supply
Consumption
The central venous oxygen saturation ScvO2
PiCCO parameters in detail
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Lungs
Pulmonary artery
Aorta
SvO2
(via pulmonary artery catheter)
ScvO2
(via central venous line)
V. cava sup.
V. cava inf.
Standard-CVC + CeVOX
(ScvO2)
PAC with optic fibre
(SvO2)
Mixed venous (SvO2) versus central venous (ScvO2) oxygen saturation
Site of measurement
PiCCO parameters in detail
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Reinhart K et al: Intensive Care Med 60, 1572-1578, 2004; Ladakis C et al: Respiration 68, 279-285, 2000
n = 29r = 0.866ScvO2 = 0.616 x SvO2 + 35.35
ScvO2
SvO2
r = 0.945
30
50
70
90
70 9050
SvO2 (%)
65
70
85
70 90
90
30 6040 80
80
ScvO2 (%)
40
60
80
806040
75
6050
Monitoring the central venous oxygen saturation
The ScvO2 correlates well with the SvO2!
PiCCO parameters in detail
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Detecting tissue hypoxia with S(c)vO2
What is “Shock”?
„Shock“ is defined as a state in which the oxgen supply cannot cover the demand, hence leading to tissue hypoxia.
Consequently, monitoring and treatment of shock states involves monitoring of oxygen supply/demand balance!
The diagnosis of „shock“ is not related to any given blood pressure, heart rate, Hb or other parameter of standard monitoring!
PiCCO parameters in detail
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S(c)vO2 is the only clinically available parameter for assessment of oxygen consumption and is highly sensitive to tissue hypoxia!
Detecting tissue hypoxia with S(c)vO2
PiCCO parameters in detail
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Early goal-directed therapyRivers E et al. New Engl J Med 2001;345:1368-77
O2-Insufflation and SedationIntubation + Ventilation
Central Venous CatheterInvasive Blood Pressure Monitoring
CVP
MAP
ScVO2
Cardiovascular Stabilisation
Volume therapy
8-12 mmHg
< 8 mmHg
65 mmHg
Inotropes
>70%70%
< 70%
no Therapy maintenance,regular reviews
< 65 mmHgVasopressors
Blood transfusion to Hematocrit 30%
Monitoring the S(c)vO2 – Clinical relevance
< 70%
Goal achieved?yes
ScVO2
PiCCO parameters in detail
Hospital 60 days
Leth
ality
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Significance of ScvO2 for therapy guidance
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Monitoring the S(c)vO2 – Clinical relevance
PiCCO parameters in detail
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Early monitoring of ScvO2 is crucial for rational and effective
hemodynamic management!
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Monitoring the S(c)vO2 – Clinical relevance
PiCCO parameters in detail
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Tissue Hypoxia despite „normal“ or high ScvO2?
?Microcirculation disturbances in SIRS / Sepsis
Monitoring the S(c)vO2 – Limitations
S. Schaudig, 2003
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SxO2 in %
PiCCO parameters in detail
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Early recognition of disturbances in global tissue oxygenation
Detection of shock of any origin
ScvO2 – very fast responding parameter to hemodynamic changes (often much quicker than heart rate or blood pressure)
valid and easy to obtain via less invasive CVC line
Decreased mortality proven by normalizing ScvO2 (Rivers study)
Control of clinical course / therapy success of hemodynamic management
Summary and key points – S(c)vO2
CeVOX sales training
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PiCCO parameters in detail
V
V
V
SV
SVSV
In order to optimize the CO you must know what the preload is!
Target AreaVolume Responsive Volume Overloaded
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Preload
SV
Importance of preload measurement
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Methods for measuring preload
traditional method: filling pressures (CVP, PCWP)
via central venous line (CVC) or pulmonary artery catheter (PAC)
RA
RV
PA
LA
LV
AortaCVC
PAC
inherent problem: conclusion from pressures on volume!
PiCCO parameters in detail
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modern method: direct measurement of the filling volumes (GEDV, ITBV)
via PiCCO-system
Left heartRight heart
Pulmonary Circulation
Lungs
Body Circulation
Methods for measuring preload
PiCCO parameters in detail
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latest concept: volume responsiveness (SVV, PPV)
via PiCCO-system
Prediction whether the heart will respond to fluid administration with an increase in cardiac output
SV
PreloadV
SV
V
SV
Methods for measuring preload
PiCCO parameters in detail
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Preload
Filling Pressures
CVP / PCWP
Volumetric Preload Parameters, Volume Responsiveness and Filling Pressures
Volume Responsiveness
SVV / PPV
Volumetric
Preload parameters
GEDV / ITBV
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PiCCO parameters in detail
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Kumar et al., Crit Care Med 2004;32: 691-699
Correlation between central venous pressure CVP and stroke volume
Role of Filling Pressures CVP / PCWP
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PiCCO parameters in detail
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Kumar et al., Crit Care Med 2004;32: 691-699
Correlation between pulmonary capillary wedge pressure PCWP with stroke volume
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Role of Filling Pressures CVP / PCWPPiCCO parameters in detail
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The filling pressures CVP and PCWP do not give an adequate assessment of cardiac preload. The PCWP is, in this regard, not superior to CVP (ARDS Network, N Engl J Med 2006;354:2564-75).
Pressure is not volume!
Influencing Factors:-Ventricular compliance-Position of catheters (PAC)-Mechanical Ventilation-Intra-abdominal hypertension
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Role of Filling Pressures CVP / PCWPPiCCO parameters in detail
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Role of Volumetric Preload Parameters GEDV / ITBV
Preload
Filling Pressures
CVP / PCWP
Volume Responsiveness
SVV / PPV
Volumetric Preload parameters
GEDV / ITBV
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PiCCO parameters in detail
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Total volume of blood in all 4 heart chambers
Left heartRight Heart
Pulmonary Circulation
Lungs
Body Circulation
GEDV = Global Enddiastolic Volume
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Role of Volumetric Preload Parameters GEDV / ITBV
PiCCO parameters in detail
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Michard et al., Chest 2003;124(5):1900-1908
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Role of Volumetric Preload Parameters GEDV / ITBV
PiCCO parameters in detail
GEDV shows good correlation with the stroke volume
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ITBV = Intrathoracic Blood Volume
Total volume of blood in all 4 heart chambers plus the pulmonary blood volume
Left heartRight heart
Pulmonary Circulation
Lungs
Body Circulation
ITBV =GEDV + PBV
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Role of Volumetric Preload Parameters GEDV / ITBV
PiCCO parameters in detail
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Sakka et al, Intensive Care Med 2000; 26: 180-187
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ITBVTD (ml)
ITBV = 1.25 * GEDV – 28.4 [ml]
GEDV vs. ITBV in 57 Intensive Care Patients
0
1000
2000
3000
0 1000 2000 3000 GEDV (ml)
ITBV is normally 1.25 times the GEDV
Role of Volumetric Preload Parameters GEDV / ITBV
PiCCO parameters in detail
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The static volumetric preload parameters GEDV and ITBV
• Are superior to filling pressures for assessing cardiac preload (Comment DSG/DIVI S2-Guidelines)
• In contrast to filling pressures are not falsified by other
pressures (Ventilation, intra-abdominal pressure)
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Role of Volumetric Preload Parameters GEDV / ITBV
PiCCO parameters in detail
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Role of the Dynamic Volume Responsiveness Parameters SVV / PPV
Preload
Filling Pressures
CVP / PCWP
Volume Responsiveness
SVV / PPV
Volumetric Preload parameters
GEDV / ITBV
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PiCCO parameters in detail
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Intrathoracic pressure
Venous return to left and right ventricle
Left ventricular preload
Left ventricular stroke volume
Systolic Arterial Blood Pressure
Intrathoracic pressure
„Squeezing “ of the pulmonary blood
Left ventricular preload
Left ventricular stroke volume
Systolic Arterial Blood Pressure
PPPPmaxmax PPPPminmin
PPPPmaxmax
PPPPminmin
Inspiration
From Reuter et al., Anästhesist 2003;52: 1005-1013
Physiology of the Dynamic Parameters of Volume Responsiveness
Expiration Inspiration Expiration
Early Inspiration Late Inspiration
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Fluctuations in blood pressure during the respiration cycle
PiCCO parameters in detail
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SV
PreloadV
SV
V
SV
Mechanical Ventilation
Fluctuations in Stroke Volume
Intrathoracic Pressure fluctuations
Changes in intrathoracic blood volume Preload changes
Fluctuations in Stroke Volume throughout the respiratory cycle
Physiology of the Dynamic Parameters of Volume Responsiveness
PiCCO parameters in detail
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SVSVmaxmax
SVSVminmin
SVSVmeanmean
Role of the Dynamic Parameters of Volume Responsiveness SVV / PPV
SVV = Stroke Volume Variation
• Is the variation in stroke volume over the respiratory cycle • Correlates well with the reaction of the hearts ejection volume during preload
enhancement (Volume Responsiveness)
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PiCCO parameters in detail
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PPV = Pulse Pressure Variation
• Is the variation in pulse pressure amplitude over the respiration cycle • Correlates equally well as SVV for volume responsiveness
PPPPmaxmax
PPPPmeanmean
PPPPminmin
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Role of the Dynamic Parameters of Volume Responsiveness SVV / PPV
PiCCO parameters in detail
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The Dynamic Preload Parameters SVV and PPV
- are good predictors of a potential increase in CO to volume administration
- are only valid with patients who are fully ventilated and who have no cardiac arrhythmias
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Role of the Dynamic Parameters of Volume Responsiveness SVV / PPV
PiCCO parameters in detail
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Summary and Key Points - preload
• The volumetric parameters GEDV / ITBV are superior for measuring cardiac preload than CVP/PCWP.
• The dynamic volume responsiveness parameters SVV and PPV can predict whether CO will respond to volume administration.
• GEDV and ITBV show what the actual volume status is, whilst SVV and PPV reflect the volume responsiveness of the heart.
• For optimal control of volume therapy it is recommended to monitor simultaneously both the static preload parameters and the dynamic parameters of volume
responsiveness (F. Michard, Intensive Care Med 2003;29: 1396).
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PiCCO parameters in detail
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Contractility is the degree of muscular power of the heart
Contractility parameters displayed by the PiCCO-Technology:
CFI = Cardiac Function Index
GEF = Global Ejection Fraction
dPmx = maximum rate of the increase in pressure
Contractility
kg
PiCCO parameters in detail
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• is the CI divided by global enddiastolic volume index
CFI = Cardiac Function Index
CICFI =
GEDI
PiCCO parameters in detail
Contractility – Thermodilution parameters
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V
SV
SV
CI
Preload
High Contractility
NormalContractility
Target AreaVolume Responders Volume Overload
LowContractility
VV
SV
V
V
VSV
SV
SV
PiCCO parameters in detail
is a parameter of both left and right ventricular contractility
has been validated successfully against echocardiographic measurement of contractility
mirrors the fraction of the preload volume which is ejected by the heart in one minute
CFI = Cardiac Function Index
Contractility – Thermodilution parameters
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• is calculated as 4 times the stroke volume divided by the global enddiastolic volume
GEF = Global Ejection Fraction
4xSVGEF =
GEDV
PiCCO parameters in detail
Contractility – Thermodilution parameters
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PiCCO parameters in detail
is –like the CFI- a parameter of both left and right ventricular contractility
has been validated successfully against echocardiographic measurement of contractility
mirrors the fraction of the preload volume which is ejected by the heart during one beat
GEF = Global Ejection Fraction
Contractility – Thermodilution parameters
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• maximum of pressure increase in the aorta (P/tmax)
• excellent correlation to the maximum pressure increase speed in the left ventricle
dPmx = maximum rate of the increase in arterial pressure
PiCCO parameters in detail
Contractility – Pulse contour parameter
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• is calculated as the difference between MAP and CVP divided by CO
• as an afterload parameter it presents a further determinant of thecardiovascular situation
• is an important parameter for controlling volume and catecholamine therapies
(MAP – CVP) x 80SVR =
CO
Afterload
SVR = Systemic Vascular Resistance
MAP = Mean Arterial PressureCVP = Central Venous PressureCO = Cardiac Output80 = Correction Factor for Units
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Afterload
SVR = Systemic Vascular Resistance
PiCCO parameters in detail
Flow (CO) =
Vasoconstriction: Flow (CO)
Vasodilation: Flow (CO)Pressure Resistance
Pressure the heart has to overcome to eject blood
If pressure is unchanged, cardiac output decreases when afterload increases
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• The contractility parameters CFI and GEF are important parameters for assessing the global systolic function and supporting the early diagnosis of myocardial insufficiency
• dPmx from the pulse contour analysis gives specific information on the left ventricular contractility
• The Systemic Vascular Resistance SVR calculated from blood pressure and cardiac output provides an additional determinant of the cardiovascular
situation, and is an important parameter for controlling volume and catecholamine therapies
Summary and Key Points – contractility and afterload
PiCCO parameters in detail
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Extravascular water content of the lung tissue
Pulmonary circulation
Left Heart
Right Heart
Lungs
The Extravascular Lung Water EVLW
EVLW = Extravascular Lung Water
Body circulation
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PiCCO parameters in detail
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The Extravascular Lung Water is the difference between the intrathoracic thermal volume and the intrathoracic blood volume.
It represents the amount of water in the lungs outside the blood vessels
Calculation of Extravascular Lung Water (EVLW)
PiCCO parameters in detail
ITTV
– ITBV
= EVLW
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Böck, Lewis, In: Practical Applications of Fiberoptics in Critical Care Monitoring,Springer Verlag Berlin - Heidelberg - NewYork 1990, pp 129-139
High Extravascular Lung Water is not necessarily identified by blood gas analysis
EVLW as a quantifier of lung edema
PaO2 /FiO2
10
20
550
30
150 2500 450
ELWI (ml/kg)
050 350
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40
Halperin et al, 1985, Chest 88: 649
EVLW as a quantifier of lung edema
Also, Chest X-ray is not able to quantify lung edema and is for a lot of patients difficult to judge, especially in critically ill patients in supine position.
r = 0.1p > 0.05
0
20
80
15-10-15 10
60
radiographic score
-80
-60
-40
-20 ELWI
PiCCO parameters in detail
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EVLWI = 7 ml/kg
EVLWI = 8 ml/kgEVLWI = 14 ml/kg
EVLWI = 19 ml/kg
Extravascular lung water index
ELWInormal range:
3 – 7 ml/kg
Pulmonary ed
ema Normal range
EVLW as a quantifier of lung edema
PiCCO parameters in detail
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ELWI (ml/kg)
> 21 n = 54
14 - 21 n = 100
7 - 14 n = 174
< 7 n = 45
Mortality(%)
10
00
n = 373*p = 0.002
20
30
40
50
60
70
80
Sturm, In: Practical Applications of Fiberoptics in Critical Care Monitoring, Springer Verlag Berlin - Heidelberg - NewYork 1990, pp 129-139
Relevance of EVLW Assessment
High Extravascular Lung Water is a predictor for mortality in intensive care patients
ELWI (ml/kg) 4 - 6
30
0
Mortality (%)
20
n = 81
40
50
60
70
80
6 - 8 8 - 10 10 - 12 12 - 16 16 - 20 > 20
90
100
Sakka et al , Chest 2002
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Intensive Care days
Mitchell et al, Am Rev Resp Dis 145: 990-998, 1992
Volume management aimed at EVLW reduction can significantly reduce time on ventilation and ICU stay, when compared to PCWP oriented therapy
Ventilation Days
PAC Group
n = 101* p ≤ 0,05
PAC GroupEVLW Group EVLW Group22 days 15 days9 days 7 days
* p ≤ 0,05
Relevance of EVLW Assessment
PiCCO parameters in detail
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PiCCO parameters in detail
PVPI = Pulmonary Vascular Permeability Index
• is the ratio of Extravascular Lung Water to Pulmonary Blood Volume
• is a measure of the permeability of the lung vessels and as such can classify the type of lung edema (hydrostatic vs. permeability caused)
EVLWPVPI =
PBV
Differentiating Lung Edema
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PiCCO parameters in detail
PVPI = Pulmonary Vascular Permeability Index
Differentiating Lung Edema
Cardiogenic Lung OedemaIncreased hydrostatic pressure with normal permeability
Permeability Lung OedemaNormal hydrostatic pressure with increased permeability
Alveolus wallAlveolus wall
Capillary Capillary
PVPI normal (1-3) PVPI raised (>3)
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Summary and key points - EVLW and PVPI
- is useful to differentiate and quantify lung edema
- for this purpose it is a unique parameter available at the bedside
- functions as a warning parameter for fluid overload
- is indexed to “predicted body weight” instead of actual body weight, allowing even better diagnosis
The Extravascular Lung Water EVLW
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PiCCO parameters in detail
The Pulmonary Vascular Permeability Index PVPI- can differentiate between a hydrostatic and a permeability caused lung edema
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PULSION monitoring philosophy: the hemodynamic triangle
The
hemodynamic triangleOptimization
of preload
Optimization of stroke volume
PiCCO allows the establishment of an adequate cardiac output through optimization of volume status whilst avoiding lung edema
Avoidance of lung edema
PiCCO parameters in detail
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PiCCO2 - get the complete picture!
Cardiac output Arterial oxygen content
Stroke volume Heart rate OxygenationSaO2
HemoglobineHb
PreloadGEDI; SVV
AfterloadSVRI; MAP
ContractilityCFI
Pulmonary Edema
ELWI
Volume? Vasopressors? Inotropics? Blood transfusion?
Global oxygenationScvO2
Oxygen delivery Oxygen consumption