physiology cardiovascular system premmed course 2013 east coast basic science course
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Physiology
Cardiovascular System
PreMMed Course 2013East Coast Basic Science Course
• What events occur in the heart each time it beats?• How much blood does the heart pump out?• What factors affect the amount of blood the heart
pumps out?• How is blood pressure related to blood flow from the
heart?• What are the normal cardiovascular response to
hypovolaemia?• How do anaesthetics affect the cardiovascular
system?
Cardiovascular System Function
• Functional components of the cardiovascular system:– Heart– Blood Vessels– Blood
• General functions these provide– Transportation
• Everything transported by the blood– Regulation
• Of the cardiovascular system– Intrinsic & extrinsic
– Protection• Against blood loss
– Production/Synthesis
Cardiovascular System Function
• To create the “pump” we have to examine the Functional Anatomy– Cardiac muscle– Chambers– Valves– Intrinsic Conduction System
Functional Anatomy of the HeartCardiac Muscle
• Characteristics– Striated– Short branched cells– Uninucleate– Intercalated discs– T-tubules larger and
over z-discs
Cardiac Ultrastructure
Cardiac Myocyte
Structural Unit:-Sarcomere
Functional Anatomy of the HeartChambers
• 4 chambers– 2 Atria– 2 Ventricles
• 2 systems– Pulmonary – Systemic
Functional Anatomy of the HeartValves
• Function is to prevent backflow– Atrioventricular Valves
• Prevent backflow to the atria• Prolapse is prevented by the chordae
tendinae– Tensioned by the papillary muscles
– Semilunar Valves• Prevent backflow into ventricles
Functional Anatomy of the HeartIntrinsic Conduction System
• Consists of “pacemaker” cells and conduction pathways– Coordinate the
contraction of the atria and ventricles
Myocardial PhysiologyAutorhythmic Cells (Pacemaker Cells)
• Characteristics of Pacemaker Cells– Smaller than
contractile cells– Don’t contain many
myofibrils– No organized
sarcomere structure• do not contribute to
the contractile force of the heart
normal contractile myocardial cell
conduction myofibers
SA node cell
AV node cells
Myocardial PhysiologyAutorhythmic Cells (Pacemaker Cells)
• Characteristics of Pacemaker Cells– Unstable membrane potential
• “bottoms out” at -60mV• “drifts upward” to -40mV, forming a pacemaker potential
– Myogenic• The upward “drift” allows the membrane to reach threshold
potential (-40mV) by itself• This is due to
1. Slow leakage of K+ out & faster leakage Na+ in» Causes slow depolarization» Occurs through If channels (f=funny) that open at negative
membrane potentials and start closing as membrane approaches threshold potential
2. Ca2+ channels opening as membrane approaches threshold» At threshold additional Ca2+ ion channels open causing more rapid
depolarization» These deactivate shortly after and
3. Slow K+ channels open as membrane depolarizes causing an efflux of K+ and a repolarization of membrane
Pacemaker Action Potential
Myocardial PhysiologyAutorhythmic Cells (Pacemaker Cells)
• Characteristics of Pacemaker Cells
Myocardial PhysiologyAutorhythmic Cells (Pacemaker Cells)
• Altering Activity of Pacemaker Cells– Sympathetic activity
• NE and E increase If channel activity– Binds to β1 adrenergic receptors which activate cAMP and
increase If channel open time– Causes more rapid pacemaker potential and faster rate of action
potentials
Sympathetic Activity Summary:
increased chronotropic effectsheart rate
increased dromotropic effectsconduction of APs
increased inotropic effectscontractility
Sympathetic Activity Summary:
increased chronotropic effectsheart rate
increased dromotropic effectsconduction of APs
increased inotropic effectscontractility
Myocardial PhysiologyAutorhythmic Cells (Pacemaker Cells)
• Altering Activity of Pacemaker Cells– Parasympathetic activity
• ACh binds to muscarinic receptors– Increases K+ permeability and decreases Ca2+ permeability =
hyperpolarizing the membrane» Longer time to threshold = slower rate of action potentials
Parasympathetic Activity Summary:
decreased chronotropic effectsheart rate
decreased dromotropic effects conduction of APs
decreased inotropic effects contractility
Parasympathetic Activity Summary:
decreased chronotropic effectsheart rate
decreased dromotropic effects conduction of APs
decreased inotropic effects contractility
Myocardial PhysiologyContractile Cells
• Special aspects– Intercalated discs
• Highly convoluted and interdigitated junctions
– Joint adjacent cells with» Desmosomes & fascia adherens
– Allow for synticial activity» With gap junctions
– More mitochondria than skeletal muscle– Less sarcoplasmic reticulum
• Ca2+ also influxes from ECF reducing storage need
– Larger t-tubules• Internally branching
– Myocardial contractions are graded!
Myocardial PhysiologyContractile Cells
• Special aspects– The action potential of a contractile cell
• Ca2+ plays a major role again• Action potential is longer in duration than a “normal” action potential
due to Ca2+ entry• Phases
4 – resting membrane potential @ -90mV0 – depolarization
» Due to gap junctions or conduction fiber action» Voltage gated Na+ channels open… close at 20mV
1 – temporary repolarization» Open K+ channels allow some K+ to leave the cell
2 – plateau phase» Voltage gated Ca2+ channels are fully open (started during initial
depolarization)3 – repolarization
» Ca2+ channels close and K+ permeability increases as slower activated K+ channels open, causing a quick repolarization
Cardiac Myocyte Action Potential
Phase 0 – Rapid DepolarisationPhase 1 – SpikePhase 2 – PlateauPhase 3 – RepolarisationPhase 4 – Diastolic potential
Myocardial PhysiologyContractile Cells
• Skeletal Action Potential vs Contractile Myocardial Action Potential
Myocardial PhysiologyContractile Cells
• Plateau phase prevents summation due to the elongated refractory period
• No summation capacity = no tetanus– Which would be fatal
Summary of Action PotentialsSkeletal Muscle vs Cardiac Muscle
Excitation Contraction Coupling
Pressure in Cardiac Chambers
Cardiac Cycle
• One complete sequence that occur during the contraction (systole) and relaxation (diastole) of the ventricular muscle
• This activity is initiated by cardiac action potential
Cardiac CycleCoordinating the activity
• Electrical Conduction Pathway
Cardiac CycleCoordinating the activity
• The electrical system gives rise to electrical changes (depolarization/repolarization) that is transmitted through isotonic body fluids and is recordable– The ECG!
• A recording of electrical activity• Can be mapped to the cardiac cycle
Conduction speeds
Tissue Conduction rate (m/s)
SA node .05
Atrial pathways 1
AV node .05
Bundle of His 1
Purkinje 4
Ventricular muscle 1
• The sum of these action potential is recorded as the ECG
P wave – atrial depolarisationPR interval – spread of excitation through the atria, AV node and bundle of HisQRS complex – spread of excitation through the ventriclesT wave – ventricular repolarisation
Cardiac CyclePhases
Atrial Contraction(A-V Valves Open, Semilunar Valves Closed)
• The first phase - initiated by the p wave of ECG - electrical depolarization of the atria.
• Atrial depolarization then causes contraction of the atrial musculature. As the atria contract, the pressure within the atrial chambers increases, which forces more blood flow across the open A-V valves, leading to a rapid flow of blood into the ventricles.
• Blood does not flow back into the vena cava because of inertial effects of the venous return and because the wave of contraction through the atria moves toward the AV valve thereby having a "milking effect."
• Atrial contraction produce a small increase in venous pressure that can be noted as the "a-wave" of the left atrial pressure. Just following the peak of the a wave is the x-descent.
• After atrial contraction is complete, the atrial pressure begins to fall causing a pressure gradient reversal across the AV valves. This causes the valves to float upward (pre-position) before closure. At this time, the ventricular volumes are maximal - end-diastolic volume (EDV).
• The left ventricular EDV (LVEDV) ~ 120 ml, represents the ventricular preload and is associated with end-diastolic pressures of 8-12 mmHg and 3-6 mmHg in the left and right ventricles, respectively.
• A heart sound is sometimes noted during atrial contraction (fourth heart sound, S4). This sound is caused by vibration of the ventricular wall during atrial contraction.
Isovolumetric Contraction(All Valves closed)
• This phase of the cardiac cycle begins with the QRS complex of the ECG - ventricular depolarization.
• This triggers excitation-contraction coupling, myocyte contraction and a rapid increase in intraventricular pressure. Early in this phase, the rate of pressure development becomes maximal - maximal dP/dt.
• The AV valves close as intraventricular pressure > atrial pressure. Ventricular contraction also triggers contraction of the papillary muscles with their attached chordae tendineae that prevent the AV valve leaflets from bulging back into the atria and becoming incompetent . Closure of the AV valves results in the first heart sound (S1) - normally split (~0.04 sec) because MV closure precedes TV
• During the time between the closure of the AV valves and the opening of the aortic and pulmonic valves, ventricular pressure rises rapidly without a change in ventricular volume - no ejection occurs.
• Ventricular volume does not change because all valves are closed during this phase. Contraction - "isovolumic" or "isovolumetric."
• The "c-wave" noted in the LAP may be due to bulging of mitral valve leaflets back into left atrium. Just after the peak of the c wave is the x'-descent.
Rapid Ejection(Aortic and Pulmonic Valves Open; AV Valves Remain Closed)
• Initial and rapid ejection of blood into the aorta and pulmonary arteries from the left and right ventricles, respectively.
• Ejection begins when the intraventricular pressures > the pressures within the aorta and pulmonary artery, which causes the aortic and pulmonic valves to open.
• Ventricular pressure normally > outflow tract pressure by a few mmHg. This pressure gradient across the valve is ordinarily low because of the relatively large valve opening (low resistance). Maximal outflow velocity is reached early in the ejection phase, and maximal (systolic) aortic and pulmonary artery pressures are achieved.
• Normally no heart sounds noted during ejection because the opening of healthy valves is silent. The presence of sounds during ejection indicate valve disease or intracardiac shunts.
• Left atrial pressure initially decreases as the atrial base is pulled downward, expanding the atrial chamber. Blood continues to flow into the atria from their respective venous inflow tracts and the atrial pressures begin to rise, and continue to rise until the AV valves open at the end of phase 5.
Reduced EjectionAortic and Pulmonic Valves Open; AV Valves Remain Closed
• Approximately 200 msec after the QRS and the beginning of ventricular contraction, ventricular repolarization occurs (T-wave of the ECG).
• Repolarization leads to a decline in ventricular active tension and therefore the rate of ejection falls.
• Ventricular pressure falls slightly below outflow tract pressure; however, outward flow still occurs due to kinetic (inertia) energy of the blood.
• Left atrial and right atrial pressures gradually rise due to continued venous return from the lungs and from the systemic circulation, respectively
Isovolumetric RelaxationAll valves closed
• When the intraventricular pressures fall sufficiently at the end of phase 4, the aortic and pulmonic valves abruptly close (aortic precedes pulmonic) causing the second heart sound (S2) and the beginning of isovolumetric relaxation.
• Valve closure is associated with a small backflow of blood into the ventricles and a characteristic notch (incisura or dicrotic notch) in the aortic and pulmonary artery pressure tracings.
• After valve closure, the aortic and pulmonary artery pressures rise slightly (dicrotic wave) following by a slow decline in pressure.
• The rate of pressure decline in the ventricles is determined by the rate of relaxation of the muscle fibers, which is termed lusitropy. This relaxation is regulated largely by the sarcoplasmic reticulum that are responsible for rapidly re-sequestering calcium following contraction.
• Although ventricular pressures decrease during this phase, volumes remain constant because all valves are closed. The volume of blood that remains in a ventricle is called the end-systolic volume ~ 50 ml in the left ventricle. The difference between the end-diastolic volume and the end-systolic volume is ~70 ml and represents the stroke volume.
• Left atrial pressure (LAP) continues to rise because of venous return from the lungs. The peak LAP at the end of this phase is termed the v-wave.
Rapid FillingA-V Valves Open
• As the ventricles continue to relax, the intraventricular pressures will at some point fall below their respective atrial pressures. When this occurs, the AV valves rapidly open and ventricular filling begins.
• Despite the inflow of blood from the atria, intraventricular pressure continues to briefly fall because the ventricles are still undergoing relaxation. Once the ventricles are completely relaxed, their pressures will slowly rise as they fill with blood from the atria.
• The opening of the mitral valve causes a rapid fall in LAP. The peak of the LAP just before the valve opens is the "v-wave." This is followed by the y-descent of the LAP. A similar wave and descent are found in the right atrium and in the jugular vein.
Reduced FillingA-V Valves open
• As the ventricles continue to fill with blood and expand, they become less compliant and the intraventricular pressures rise. This reduces the pressure gradient across the AV valves so that the rate of filling falls.
• In normal, resting hearts, the ventricle is about 90% filled by the end of this phase. In other words, about 90% of ventricular filling occurs before atrial contraction.
• Aortic pressure and pulmonary arterial pressures continue to fall during this period.
Cardiac Cycle
LV Pressure-Volume Relationship
Pressure Volume Loop
Cardiac Output
• Volume of blood ejected by each ventricle per minute
• CO = Stroke Volume, SV X Heart Rate
= l/min
• Cardiac Index = CO/body surface area
= l/min/m2
• Factors Affecting Stroke Volume– Degree of filling of ventricle, Preload– Contractility of myocardium– Resistance against which the ventricle has to
work, Afterload
Preload
• The load on the myocardial muscle just prior to the onset of contraction.
• The more a muscle fibre is stretched before being stimulated to contract, the greater its force of contraction.
• Limited by internal molecular structure of muscle, that above a critical (optimal) point further lengthening reduces force of contraction.
Effect of Preload on PV loop
Myocardial Contractility
• (Intrinsic) ability of the cardiac muscle fibres to contract.
• Independent of the degree of preload and afterload.
• Referred as degree of inotropy
• +ve inotropic– Sympathetic nervous system –
catecholamines• -ve inotropic
– Acidosis– Hypoxia– Hypocalcaemia– Drugs – anaesthetics, antiarrhythmic
Effect of Inotropy on PV loop
Afterload• The impedence to the ejection of blood from the
heart into the arterial circulation.• At the end of diastole, venticular muscle starts to
contract.• Need to overcome forces that preventing it;
– Tension in ventricular wall– Resistance to ejection of blood from ventricle
• Approximated as– L vent afterload – resistance by systemic circulation –
Systemic Vascular Resistance (SVR)– R vent afterload – resistance by pulmonary circulation –
Pulmonary Vascular Resistance (PVR)
Effect of Afterload on PV loop
Law Of Laplace
T = P x r/wt
Tension = Pressure x Radius / wall thickness
How does Laplace Work?
Heart Rate• Heart has an intrinsic pacemaker, the
sinoatrial node. ~ discharged around 100 beats/min
• Control by autonomic nervous system• Sympathetic stimulation – increase HR -
+ve chronotropic• Parasympathetic stimulation (Vagus) –
decrease HR - -ve chronotropic
CO tends to fall when heart rate surpasses 150/min due to inadequate filling time. Too low heart rate, CO also tends to drop due to insufficient heart rate
Receptor typeLocation Effects
Alpha-1 Blood vessels Vasoconstriction
Alpha-2 Blood vessels Vasoconstriction
Beta-1 Heart Increase heart rateIncrease force of contraction
Beta-2 Blood vesselsLungs
VasodilatationBronchodilatation
Cardiac Reflexes
• Baroreceptor reflex• Chemoreceptor reflex• Bainbridge reflex• Bezold jarish reflex• Valsalva maneuver• Cushings reflex• Occulocardiac reflex
Baroreceptor Reflex
• Stretch receptors in walls of heart and blood vessels
• Responsible for maintenance of blood pressure
Baroreceptor Reflex↑ BP
↑ BR in carotid sinus & aortic arch
Sinus nerve & Aortic nerve
IX & X nerve
N. solitarius
↑ vagal tone
↓ HR
Chemoreceptor Reflex↓pO2 ↑ pCO2 & ↓pH
↑ CR in carotid body & aortic arch
Sinus nerve & Aortic nerve
IX & X nerve
↑ Respiratory centre
↑ ventilatory drive
Bainbridge Reflex
Venous engorgement of atria & great veins
Stimulation of stretch receptors
X nerve
CVS center medulla
↓ Vagal tone
↑ HR
Bezold Jarish Reflex
Ischemia
Receptors in LV
X nerve
Reflex bradycardia, Hypotension & coronary artery dilation
Valsalva Maneuver
• Forced expiration against closed glottis• Increase in intrathoracic pressure
↑ Intrathoracic pressure → ↑CVP → ↓ V.R → ↓ CO &BP → sensed by BR → ↑ HR & contractility
• When glottis opens
↑ VR → ↑ contractility → ↑ BP →sensed by BR → ↓ HR & BP
Initial Pressure Rise Reduced VR & Compensation Pressure Release Return of CO
On application of expiratory force, pressure rises inside the chest forcing blood out of the pulmonary circulation into the L atrium. This causes a mild rise in SV.
Return of systemic blood to the heart is impeded by the pressure inside the chest. The output of the heart is reduced and SV falls. The fall in SV reflexively causes blood vessels to constrict with some rise in pressure. This compensation can be quite marked with pressure returning to near or even above normal, but the cardiac output and blood flow to the body remains low. During this time the PR increases.
The pressure on the chest is released, allowing the pulmonary vessels and the aorta to re-expand causing a further initial slight fall in SV due to decreased L ventricular return and increased aortic volume, respectively. Venous blood can once more enter the chest and the heart, CO begins to increase.
Blood return to the heart is enhanced by the effect of entry of blood which had been dammed back, causing a rapid increase in CO. The SV usually rises above normal before returning to a normal level. With return of BP, the PR returns towards normal.
• Clinical Uses of Valsalva Manoeuvre;– Reversion of supraventricular tachycardia– Testing autonomic function– Aid in assessment of some heart murmurs
Cushings Reflex ↑ Intracranial pressure
Cerebral ischemia
↑ VMC
↑SNS - ↑BP
↑BR
↑CIC
↑Vagal tone
reflex bradycardia ↓ HR
Occulocardiac Reflex
Pressure on eye
long & short ciliary nvs
ciliary ganglion
gasserion ganglia
↑ PNS → BRADYCARDIA
Systemic Circulation
Physical laws governing blood flow and blood pressure
• Flow of blood through out body = pressure gradient within vessels X resistance to flow
- Pressure gradient: aortic pressure – central venous pressure
- Resistance: -- vessel radius -- vessel length -- blood viscosity
Factors promoting total peripheral resistance (TPR)
• Total peripheral resistance = TPR -- combined resistance of all vessels -- vasodilation resistance decreases -- vasoconstriction resistance increases
Vasculature
Arteries and blood pressure
• Pressure reservoir• Arterial walls are able to expand and recoil because of the
pressure of elastic fibers in the arterial wall• Systolic pressure: maximum pressure occurring during systole• Diastolic pressure: pressure during diastole
Capillaries
• Allow exchange of gases, nutrients and wastes between blood and tissues
• Overall large surface area and low blood flow
• Two main types:- continuous capillaries:
narrow space between cells permeable to small or lipid soluble molecules
- fenestrated capillaries: large pores between cells large molecules can pass
Movement of materials across capillary walls
• Small molecules and lipid soluble molecules move by diffusion through the cell membrane
• Larger molecules, charged molecules must pass through membrane channels, exocytosis or in between 2 cells
• Water movement is controlled by the capillary hydrostatic and osmotic pressures
Forces controlling water movement• Arterial side of the capillary:
– High capillary hydrostatic pressure (BHP), lower capillary osmotic pressure (BOP, due to proteins and other molecules in the blood) Net filtration pressure pushes fluid from the blood toward the tissue (but the proteins remain in the capillary
• Venous side of the capillary:- Lower hydrostatic pressure (due to resistance) and higher capillary osmotic pressure Net filtration pressure moves fluid back toward the capillary
• Interstitial fluid hydrostatic (IFHP) and osmotic pressures (IFOP) remain overall identical
Starling’s Hypothesis• A quote from Starling (1896) "... there must be a balance between the hydrostatic pressure of the blood in the capillaries and the osmotic attraction of the blood for the surrounding fluids. " " ... and whereas capillary pressure determines transudation, the osmotic pressure of the proteids of the serum determines absorption.“
Starling, 1896
• Starling’s hypothesis - the fluid movement due to filtration across the wall of a capillary is dependent on the balance between the hydrostatic pressure gradient and the oncotic pressure gradient across the capillary.
• The four Starling’s forces are:– hydrostatic pressure in the capillary (Pc) – hydrostatic pressure in the interstitium (Pi) – oncotic pressure in the capillary (∏ c ) – oncotic pressure in the interstitium (∏ i )
• The balance of these forces allows calculation of the net driving pressure for filtration.
• Net Driving Pressure = [ ( Pc - Pi ) - ( ∏c - ∏i ) ]
CAPILLARY FILTRATION
HYDROSTATICFORCES
OSMOTIC FORCES
Arterial PressureVenous PressurePre-post Capillary Res.Interstitial Fluid Pressure
ONCOTIC PRESSURE
Albumin
BALANCESTARLING’S HYPOTHESIS
Qf = k (Pc + i) - (Pi + p)
Veins
• Veins are blood volume reservoir
• Due to thinness of vessel wall less resistance to stretch = more compliance
Normal distribution of blood volume
• Heart 7%• Pulmonary circulation 9%• Systemic circulation Arteries 15% Capillaries 5% Veins 64%
Factors influencing venous return
• 1- Skeletal muscle pump and valves
• 2- Respiratory pump
• 3- Blood volume
• 4- Venomotor tone
Role of The Parts of Circulation
Aorta & Large Elastic Arteries Auxillary pump to obtain continuous (though pulsatile) flow throughout the cardiac cycle
Muscular Arteries Distribute oxygenated blood to the tissues
Arterioles Resistance vessels – determined the systemic vascular resistance & the distribution of the CO
Capillaries Exchange vessels – gas, nutrients and waste
Veins Capacitance vesselsReturn blood to the heart
Heart & Lung Contain the central blood volume – Pump & Gas exchange function
All together Closed circuit with pump-oxygenator designed for distribution & exchange
Mean Arterial Pressure And Its Regulation
• Regulation of blood flow in arteries
- Intrinsic control
- Extrinsic control
-Neural control
-Hormonal control
* Control of blood vessel radius
* Control of blood volume
Regulation of blood flow in arteries
• It is important to adjust blood flow to organ needs Flow of blood to particular organ can be regulated by varying resistance to flow (or blood vessel diameter)
• Vasoconstriction of blood vessel smooth muscle is controlled both by the ANS and at the local level.
• Four factors control arterial flow at the organ level:
- change in metabolic activity- changes in blood flow- stretch of arterial smooth
muscle- local chemical messengers
Autoregulation
Definition:
Intrinsic ability of an organ to maintain a constant
blood flow despite changes in perfusion pressure,
independent of any neural or humoral influences
Myogenic Mechanism• The myogenic mechanism is how arteries and arterioles react
to an increase or decrease of blood pressure to keep the blood flow within the blood vessel constant
• The smooth muscle of the blood vessels reacts to the stretching of the muscle by opening ion channels, which cause the muscle to depolarize, leading to muscle contraction. This significantly reduces the volume of blood able to pass through the lumen, which reduces blood flow through the blood vessel. Alternatively when the smooth muscle in the blood vessel relaxes, the ion channels close, resulting in vasodilation of the blood vessel; this increases the rate of flow through the lumen.
From: AJP - Heart October 2008 vol. 295 no. 4 H1505-H1513
Metabolic Mechanism
• Any intervention that results in an inadequate oxygen (nutrient) supply for the metabolic requirements of the tissues results in the formation of vasodilator substances which increase blood flow to the tissues
Lack of oxygen? Formation of vasodilators?
Combination of both??
Metarteriole
Precapillary Sphincter
Capillary
Relaxation of smooth muscle
Increased Blood Flow
Intrinsic control of local arterial blood flow
• Change in metabolic activity– Usually linked to CO2 and
O2 levels (↑ CO2 vasodilation ↑ blood flow) intrinsic control
• Changes in blood flow
- decreased blood flow increased metabolic wastes vasodilation
• Stretch of arterial wall = myogenic response
- Stretch of arterial wall due to increased pressure reflex constriction
• Locally secreted chemicals can promote vasoconstriction or most commonly vasodilation
- inflammatory chemicals, (nitric oxide, CO2)
Extrinsic control of blood pressure
• Two ways to control BP:- Neural control- Hormonal control
** Use negative feedback
Neural control of BP• Baroreceptors:
carotid and aortic sinuses sense the blood pressure in the aortic arch and internal carotid send signal to the vasomotor center in the medulla oblongata
• Other information are sent from the hypothalamus, cortex
•
Neural control of BP
• The vasomotor center integrates all these information
• The vasomotor sends decision to the ANS center:- Both parasympathetic and sympathetic innervate the S/A node
can accelerate or slow down the heart rate- The sympathetic NS innervates the myocardium and the smooth
muscle of the arteries and veins promotes vasoconstriction
Hormonal control of BP
• Hormones can control blood vessel radius and blood volume, stroke volume and heart rate
• On a normal basis, blood vessel radius and blood volume are the main factors
• If there is a critical loss of pressure, then the effects on HR and SV will be noticeable (due to epinephrine kicking in)
• Control of blood vessel radius - Epinephrine - Angiotensin II - Vasopressin (?)
• Control of blood volume- Anti-diuretic hormone (vasopressin)- Aldosterone
• Control of heart rate and stroke volume- Epinephrine
Control of blood vessel radius• Epinephrine: secreted by the
adrenal medulla and ANS reflex increase HR, stroke volume and promotes vasoconstriction of most blood vessel smooth muscles.
• Angiotensin II promotes vasoconstriction
• Angiotensin II secretion:- Decreased flow of filtrate in kidney
tubule is sensed by the Juxtaglomerular apparatus (a small organ located in the tubule) secretion of renin
- Renin activates angiotensinogen, a protein synthesized by the liver and circulating in the blood angiotensin I
- Angiotensin I is activated by a lung enzyme, Angiotensin-Activating Enzyme (ACE), angiotensin II
- Angiotensin II is a powerful vasoconstricted of blood vessel smooth muscles
Control of blood volume
• Anti-diuretic hormone = ADH
- Secreted by the posterior pituitary in response to ↑blood osmolarity (often due to dehydration)
- Promote water reabsorption by the kidney tubules H2O moves back into the blood less urine formed
Control of blood volume
• Aldosterone:- Secretion by the adrenal
cortex triggered by angiotensin II
- Promotes sodium reabsorption by the kidney tubules (Na+ moves back into the blood)
- H2O follows by osmosis- Whereas ADH promotes H2O
reabsorption only (in response to dehydration), aldosterone promotes reabsorption of both H2O and salt (in response to ↓ BP)
Coronary Circulation
Coronary Blood flow – 200-250 ml/min @ 5% CO
SA node:-59% RCA. 38% LCAAV node:- 90% RCA 10% LCA
Distribution Of Coronary Circulation
Left Coronary Artery •Ant descending branch.•Right bundle branch.•Left bundle branch.•Ant & post papillary muscle.•Ant lat left ventricle.
Circumflex Branch Lateral left ventricle.
Right Coronary Artery •SA and AV nodes.•RA and RV•Post interventricular septum.•Inter atrial septum.•Post fascicle of LB
Occlusion in the….• Anterior descending artery: leads V3-5.
• Left circumflex artery: leads I and aVI.• Right coronary artery: leads II, III and aVF.
Coronary Perfusion
• Coronary perfusion is unique in that it is INTERMITTENT rather than continuous
• During contraction, intramyocardial pressures approach that of systemic pressures completely occluding the intramyocardial portions of the coronary arteries
Coronary Perfusion
• Thus, Coronary perfusion pressure is usually determined by the difference between aortic pressure and ventricular pressure and the left ventricle is almost totally perfused entirely during DIASTOLE
• As a determinant of myocardial blood flow, arterial diastolic pressure is MORE important than Mean Arterial Pressure (MAP)
Coronary Perfusion
• Decreases in Aortic pressure or increases in ventricular end-diastolic pressures can reduce coronary perfusion
• Increases in heart rate also decrease coronary perfusion because the faster the heart beats, the less time there is for diastole for perfusion to take place
Venous Drainage Of The Heart
• Coronary sinus:- drains the great cardiac vein, middle cardiac vein and the posterior cardiac vein.
• Anterior cardiac veins.
• Direct:- arterioluminal, arteriosinusoidal and thebasian veins.
Cerebral Circulation
Anterior Cerebral artery
Middle Cerebral artery
Posterior Cerebral artery
InternalCarotidartery
(70% of CBF)
Vertebral artery
Basilar artery 30%
ofCBF
Arterial supply
Cerebral CirculationCircle of Willis
Basilar A
Internal CA
Middle CA
Anterior CA
Vertebral A
Posterior CA
Cerebral Artery Areas
1. anterior cerebral
2. Middle cerebral
3. Penetrating branches of middle cerebral
4. anterior choroidal
5. Posterior cerebral
1
23
45
5
Cerebral CirculationVenous drainage
Cerebral Physiology• 2% of BW • 20% of Total body O2 consumption
– (60% used for ATP formation)
• CMR O2 3-3.8mL /100 gm/min– (50 ml /min in Adult)
• 15% 0f CO (750 ml/min@ 50 ml/100g/min)• Glucose consumption 5 mg/100gm/min
– (25% of total body consumption/min)
• High oxygen consumption but no reserve• Grey matter of cerebral cortex consumes more• Directly proportional to electrical activity
– (Hippocampus & cerebellum most sensitive to hypoxic injury)
Cerebral Perfusion Pressure
• CPP = MAP—ICP (or CVP whichever is greater)– Normally 80 to 100mm Hg
• ICP is <10 mmHg so CPP primarily dependent on MAP
• Increase in ICP>30 =CPP & CBF compromise• CPP<50 slowing of EEG
– 25-40 Flat EEG– CPP <25 result in Irreversible brain death
Factors Influencing CBF
• Chemical/metabolic• Myogenic• Rheologic• Neurologic
Chemical/Metabolic
• Cerebral Metabolic Rate– Arousal– Seizure– Mental State– Anaesthetic– Temperature
• PaCO2• PaO2• Vasoactive drugs
– Anaesthetic– Vasodilators– Vasopressors
Cerebral Metabolic Rate
• Increased neuronal activity results in increased local brain metabolism
• Local metabolic factors play a major role in these adjustments in CBF.
• CMR is influenced by several phenomena in the neurosurgical environment– functional state of the nervous system – anesthetic agents, temperature
Functional State
• CMR decreases during sleep and increases during sensory stimulation, mental tasks, or arousal of any cause.
• During epileptoid activity, CMR increases may be extreme, whereas CMR may be substantially reduced in coma.
Temperature
• CMR decreases by 6 - 7 %/ oC of temperature reduction.
• However, in contrast to anesthetic agents, temperature reduction beyond that at which EEG suppression first occurs does produce a further decrease in CMR
The effect of temperature reduction on the cerebral metabolic rate of oxygen
Temperature on CBF
6-7 % decrease /0C FALL IN TEMP.
37-42 0C - CBF & CMRO2
>42 0C - CMRO2
20 0C - ISOELECTRICITY
Partial Pressure of Carbon Dioxide
• CBF varies directly with PaCO2
• The effect is greatest within the range of physiologic PaCO2 variation.
• CBF changes 1 to 2 mL/100 g/min for each 1 mm Hg of change in PaCO2around normal PaCO2 values.
• This response is attenuated below a Pa CO2 of 25 mm Hg.
• The changes in CBF caused by PaCO2 are apparently dependent on pH alterations in the extra cellular fluid of the brain
• Note that in contrast to respiratory acidosis, acute systemic metabolic acidosis has little immediate effect on CBF because the blood-brain barrier (BBB) excludes the hydrogen ion from the perivascular space.
• Although the CBF changes in response to PaCO2 alteration occur rapidly, they are not sustained.
• In spite of the maintenance of an elevated arterial pH, CBF returns to normal over 6 to 8 hours because cerebrospinal fluid (CSF) pH gradually normalizes as a result of the extrusion of bicarbonate.
• Acute normalization of PaCO2 results in a significant CSF acidosis (after hypocapnia) or alkalosis (after hypercapnia).
• The former results in increased CBF with a concomitant intracranial pressure (ICP) increase that will depend on the prevailing intracranial compliance. The latter conveys the theoretic risk of ischemia.
Partial Pressure of Oxygen
• Changes in PaO2from 60 - 300 mmHg have little influence on CBF.
• When the PaO2is less than 60 mm Hg, CBF increases rapidly .
• At high PaO2values, CBF decreases modestly.
• The mechanisms mediating the cerebral vasodilation during hypoxia are not fully understood, but they may include neurogenic effects initiated by peripheral and/or neuraxial chemoreceptors as well as local humoral influences
• At 1 atm O2,CBF is reduced by 12 percent.
Myogenic Regulation
Autoregulation refers to the capacity of the cerebral circulation to adjust its resistance in order to maintain CBF constant over a wide range of mean arterial pressure
Neurogenic Regulation
• There is considerable evidence of extensive innervation of the cerebral vasculature.
• The density of innervation declines with vessel size, and the greatest neurogenic influence appears to be exerted on larger cerebral arteries.
• This innervation includes autonomic, serotonergic, and vasoactive intestinal peptide-ergic (VIPergic) systems of extra-axial and intra-axial origin.
Viscosity Effects
• Blood viscosity can influence CBF.• Hematocrit is the single most important
determinant of blood viscosity. • In healthy subjects, hematocrit variation
within the normal range (33-45%) probably results in only trivial alteration of CBF.
• Beyond this range, changes are more substantial.
Guyton, Coleman, Granger (1972) Ann. Rev. Physiol.
kidneymuscles
circulatorydynamics
capillary membranedynamics
thirst
ADHcontrol
angiotensincontrol
aldosteronecontrol
electrolytes& cellwater
tissue fluids, pressures,
gelred cells,viscosity
autonomiccontrol
pulmonarydynamics
local bloodflow
control
oxygendelivery
heart rate…heart
hypertrophy
"a Systems Approach for PHysiological Integration of Renal, cardiac, and respiratory functions"
Guyton's modular Systems Model for blood pressure regulation
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