Notes for CVS
Dr. Sabir HussainHuman Physiology
The Heart
Location and Size of Heart
• Located in thoracic cavity in mediastinum
• About same size as closed fist– base is the wider
anterior portion– apex is tip or point
Pericardium: Heart Covering
Fibrous Pericardium
• Rests on and is attached to diaphragm
• Tough, inelastic sac of fibrous connective tissue
• Continuous with blood vessels entering, leaving heart at base
• Protects, anchors heart, prevents overstretching
Parietal (Outer) Serous Pericardium
• Thin layer adhered to inside of fibrous pericardium
• Secretes serous (watery) lubricating fluid
Layers of the Heart Wall
• The wall of the heart is composed of three distinct layers. From superficial to deep they are: – The epicardium – The myocardium– The endocardium
Layers of the Heart Wall
Chambers of the Heart
• The heart has 4 Chambers:
– The upper 2 are the right and left atria.
– The lower 2 are the right and left ventricles.
Chambers of the Heart
Chambers of the Heart
Valves of the Heart• Function to prevent
backflow of blood into/through heart
• Open, close in response to changes in pressure in heart
• Four valves
Heart Valves
Valves
Valves
Valves• Surprisingly, perhaps, there are no valves guarding the junction between the
venae cavae and the right atrium or the pulmonary veins and the left atrium.
As the atria contract, a small amount of blood does
flow backward into these vessels, but
it is minimized by the way the atria
contract, which compresses,
and nearly collapses the
venous entry points.
Heart Valves
Blood Flow• The body’s blood flow can best be understood as two circuits
arranged in series. The output of one becomes the input of the
other:
– Pulmonary circuit ejects blood into the pulmonary trunk and
is powered by the right side of the heart.
– Systemic circuit ejects blood into the aorta, systemic arteries,
and arterioles and is powered by the left side of the heart.
The right-sided Pulmonary Circulation
• Starting with the venous return to the heart, deoxygenated blood flows into the right atrium from 3 sources (the two vena cavae and the coronary sinus).
• Blood then follows a pathway through the right heart to the lungs to be oxygenated.
Blood Flow
The left-sided Systemic Circulation
Blood Flow• Oxygenated blood returns to the left heart to
be pumped through the outflow tract of the systemic circulation.
Coronary Vessels– The myocardium (and other tissues of the thick cardiac walls) must get
nutrients from blood flowing through the coronary circulation.• Starting at the aortic root, the direction of blood flow is from the aorta to the
left and right coronary arteries (LCA, RCA):– LCA to anterior interventricular
and circumflex branches– RCA to marginal and
posterior atrioventricular branches
Coronary Vessels• The coronary arteries and veins have been painted
in this anterior view of a cadaver heart:
• Coronary veins all collect into the coronary sinus on the back part of
the heart:
Coronary Vessels
Arteries and Veins• Arteries are vessels that always conduct blood away
from the heart – with just a few exceptions, arteries contain oxygenated blood.
• Most arteries in the body are thick-walled and exposed to high pressures and friction forces.
Arteries and Veins• Veins are vessels that always bring blood back to the
heart - with just a few exceptions, veins contain deoxygenated blood.
• Most veins in the body are thin-walled and exposed to low pressures and minimal friction forces.
Arteries and Veins
View of the front of the heart
Arteries and Veins
• Cardiac muscle, like skeletal muscle, is striated. Unlike skeletal muscle, its fibers are shorter, they branch, and they have only one (usually centrally located) nucleus.
• Cardiac muscle cells connect to and communicate with neighboring cells through gap junctions in intercalated discs.
Cardiac Muscle Tissue
By: Dr. Sabir Hussain Specialized excitatory and conductive system of the Heart:SA node - Sinus node or sinoatrial node, initiates the cardiac impulse Internodal pathway - SA to AV node AV node - delays impulse from the atria to the ventricles AV bundle - conducts from AV node to the ventricles Purkinje Fibers - conducts impulses to all parts of the ventricles.
The Sinus Node controls the heart rate: The membrane potential of sinus node is -55 to -60 mV The heart rate is caused by following four factors:. The fast sodium channels are inactivated at the normal resting potential, but there is slow leakage of sodium in the fiber.. Between action potentials the resting potential gradually increases because of slow leakage sodium until the potential reaches -40mV
. At this time, the calcium-sodium channels become activated, allowing rapid entry of sodium and calcium and thus causing the action potential.. Greatly increased numbers of potassium channels open, allowing potassium to escape from the cells, within about 100 to 150 ms after the calcium-sodium open. This returns the membrane potential to its resting potential, and the self excitation cycle starts again with sodium leaking slowly into the sinus node fibers.
The Internodal and interatrial pathways transmit impulses in the atrium. There are three internodal pathways - the anterior, the middle and the posterior internodal pathway - that carry impulses from the SA node to the AV node. Small bundles of atrial muscle fibers transmit impulses more rapidly than the normal atrial muscle -like the anterior interatrial band, conducts impulses from the right atrium to the anterior part of the left atrium.
The AV node delays impulses from the atria to the ventricles. This delayed time allows the atria to empty into the ventricles before ventricular contraction. The delay in the AV node is achieved by slow conduction: (1) membrane potential is much less negative in the AV node and the bundle than in the normal cardiac muscle. (2) Few gap junctions exist between the cells in the AV node and the bundle, so that resistance to ion flow is great.
The transmission of impulses through the Purkinje system and the cardiac muscle is rapid. The action potentials travel at a velocity of 1,5 to 4,0 m/s, which is 6x the velocity of cardiac muscle.The high permeability of the gap junctions at the intercalated discs between the Purkinje fiber cells likely causes the high velocity of transmission.
The atrial and ventricular syncytia are separate and insulated from one another. Separated by a fibrous barrier that acts as an insulator - forcing atrial impulses to enter through the AV bundle. The transmission of impulses through cardiac muscle travel at a velocity of 0.3 to 0.5 m/s. Travel from the endocardium to the epicardium in 0.03ms.
Control of excitation and conduction in the Heart.The sinus node is the normal pacemaker of the heart. The intrinsic discharge rate for the SA node, 70-80bpm, AV-node 40-60bpm, Purkinje system 15-40bpm. An ectopic pacemaker may develop a rhythmic rate faster than the SA node - the most common location would be in the AV node or the AV bundle.
AV block occurs when impulses fail to pass from the aorta to the ventricles. After a sudden block, the purkinje fibers do not emit rhythmic impulses for 5 to 30 seconds because it has been overridden by the sinus rhythm. During this time the ventricles fail to contract, and person may faint because of the lack of cerebral perfusion. This is known as the STOKES-ADAMS SYNDROME.
Control of Heart Rhythmicity and Conduction by the Cardiac Nerves: Sympathetic and Parasympathetic. Parasympathetic (vagal) stimulation slows the cardiac rhythm - through acetylcholine release causes:1. The rate of sinus node discharge decrease2. The excitability of the fibers between the atrialmuscle and the AV node to decrease.
The heart rate can decrease to half normal, but strong vagal stimulation can temporarily stop the heartbeat. The purkinje fibers then develop their own rhythmicity at 15 to 40 bpm. This is called ventricular escape. The mechanism of vagal effects on the heart are as follows:1.) Acetylcholine increases the permeability of the sinus node and the AV fibers to potassium; this causes hyperpolarization of these tissues and makes them less excitable.2.) The membrane potential of the Sinus Node fibers decrease from -55 to 60mV to -65 to -75mV.The normal upward drift in the membrane potential is caused by sodium leakage in these tissues requires a much longer time to reach self-excitation.
Sympathetic Stimulation increases cardiac rhythm.. The rate of Sinus Node discharge increases. The cardiac impulse conductance rate increases in all parts of the heart. The force of contraction increases in both atrial and ventricular muscle. Sympathetic stimulation releases norepinephrine - increasing the permeability to sodium and calcium, increasing the resting membrane potential and makes the heart more excitable, and therefore increasing the heart rate.The greater calcium permeability increases the force of contraction of cardiac muscle.
Dr. Sabir Hussain
Rhythmical Excitation of the Heart
Rhythmical Excitation of the Heart
The rhythmical electrical impulses in a normal heart allows:• The atria to contract about one sixth of a second
ahead of ventricular contraction.• Allows ventricular filling before they pump the blood
through the lungs and peripheral circulation.• Allows all portions of the ventricles to contract
almost simultaneously.
Sinus (Sinoatrial Node)
Strip of specialized cardiac muscle
Sinus nodal fibers connect directly with the atrial muscle fibers.
Have the capability of self-excitation, a process that can cause automatic rhythmical discharge and contraction
Mechanism of Sinus Nodal Rhythmicity.
• R.M.P of the sinus nodal fiber has a negativity of about -55 to -60 millivolts, in comparison with -85 to -90 millivolts for the ventricular muscle fiber.
• Cell membranes of the sinus fibers are naturally leaky to sodium and calcium ions.
• At -55 mV, the fast sodium channels already become “inactivated”.
• The atrial nodal action potential is slower to develop than the action potential of the ventricular muscle.
The inherent leakiness of the sinus nodal fibers to sodium and calcium ions causes their self-excitation.
Transmission of the Cardiac Impulse Through the Atria
• The A-V node is located in the posterior wall of the right atrium immediately behind the tricuspid valve
• Action potentials originating in the sinus node travel outward into the atrial muscle fibers and to the A-V node.
• Impulse, after traveling through the internodal pathways, reaches the A-V node about 0.03 second after its origin in the sinus node.
One-Way Conduction Through the A-V Bundle.
• The impulse is delayed more than 0.1 second in the A-V nodal region before appearing in the ventricular septal A-V bundle.
• Once it has entered this bundle, it spreads very rapidly through the Purkinje fibers to the entire endocardial surfaces of the ventricles.
• Then the impulse once again spreads slightly less rapidly through the ventricular muscle to the epicardial surfaces.
Special Purkinje fibers lead from the A-V node through the A-V bundle into the ventricles.
Diminished numbers of gap junctions between successive cells in the conducting pathways allowing resistance to conduction of excitatory ions from one conducting fiber to the next.
Distal portion of the A-V bundle passes downward in the ventricular septum for 5 to 15 millimeters toward the apex of the heart.
Transmit action potentials at a velocity of 1.5 to 4.0 m/sec
Transmission in the Ventricular Purkinje System
Abnormal Pacemakers (Ectopic pacemakers)
A pacemaker elsewhere than the sinus node is called an “ectopic” pacemaker.
• The discharge rate of the sinus node is considerably faster than the natural self-excitatory discharge rate of either the A-V node or the Purkinje fibers.
• Under abnormal conditions, few other parts of the heart can exhibit intrinsic rhythmical excitation in the same way like the sinus nodal fibers (A-V nodes and Purkinje fibres).
• The cardiac impulse arrives at almost all portions of the ventricles within a narrow span of time, exciting the first ventricular muscle fiber only 0.03 to 0.06 second ahead of excitation of the last ventricular muscle fiber.
Why Sinus node controls heart rhythymicity
Control of Heart Rhythmicity and Impulse Conduction The Sympathetic and Parasympathetic Nerves
Parasympathetic Nerves Sympathetic Nerves
Releases acetylcholine
Decreases heart rhythm and excitability.
Excitatory signals are no longer transmitted into the ventricles.
Ventricular Escape
Increased permeability of the fiber membranes to potassium ions
Releases norepinephrine at sympathetic endings.
Increases the rate of sinus nodal discharge.
Increases the overall heart activity.
Increases the permeability of Na+ and Ca2+ ions.
Abnormal Heart Rhythms
• Atrial fibrillation• Superventricular tachycardia(Electric impulses travel from ventricle to atria)Ventricular tachycardia (ventricles don’t have
time to fill up properly)
• Bradycardia (Slow heart beat)
Pacemaker Implantation
Autorhythmicity
• The rhythmical electrical activity produced
in heart is called autorhythmicity. Because
heart muscle is autorhythmic, it does not
rely on the central nervous system to
sustain a lifelong heartbeat.
• During embryonic development, about 1% of all of the muscle cells of the heart form a network or pathway called the cardiac conduction system. This specialized group of myocytes
is unusual in that they have the ability to spontaneously depolarize.
Autorhythmicity
Membrane of two cells clearly seen. The spread of ions through gap junctions of the Intercalated discs (I) allows the AP to pass
from cell to cell
Autorhythmicity• Autorhythmic cells spontaneously depolarize at a given rate,
some groups faster, some groups slower. Once a group of
autorhythmic cells reaches threshold and starts an action
potential (AP), all of the cells in that area of the heart also
depolarize.
Cardiac Conduction• The self-excitable myocytes that "act like nerves" have the 2
important roles of forming the conduction system of the heart
and acting as pacemakers within that system.
• Because it has the fastest rate of depolarization, the normal
pacemaker of the heart is the
sinoatrial (SA) node, located in the
right atrial wall just below
where the superior vena
cava enters the chamber.
Cardiac Conduction
Spontaneous
Depolarization of autorhythmic fibers in the SA
node firing about once every 0.8 seconds, or 75
action potentials per minute
Frontal plane
Right atrium
Right ventricle
Left atrium
Left ventricle
Anterior view of frontal section
Frontal plane
Left atrium
Left ventricle
Anterior view of frontal section
SINOATRIAL (SA) NODE1
Right atrium
Right ventricle
Frontal plane
Left atrium
Left ventricle
Anterior view of frontal section
SINOATRIAL (SA) NODE
ATRIOVENTRICULAR(AV) NODE
1
2
Right atrium
Right ventricle
Frontal plane
Left atrium
Left ventricle
Anterior view of frontal section
SINOATRIAL (SA) NODE
ATRIOVENTRICULAR(AV) NODE
ATRIOVENTRICULAR (AV)BUNDLE (BUNDLE OF HIS)
1
2
3
Right atrium
Right ventricle
Frontal plane
Left atrium
Left ventricle
Anterior view of frontal section
SINOATRIAL (SA) NODE
ATRIOVENTRICULAR(AV) NODE
ATRIOVENTRICULAR (AV)BUNDLE (BUNDLE OF HIS)
RIGHT AND LEFTBUNDLE BRANCHES
1
2
3
4
Right atrium
Right ventricle
Frontal plane
SINOATRIAL (SA) NODE
ATRIOVENTRICULAR(AV) NODE
Left atrium
Left ventricle
Anterior view of frontal section
ATRIOVENTRICULAR (AV)BUNDLE (BUNDLE OF HIS)
RIGHT AND LEFTBUNDLE BRANCHES
PURKINJE FIBERS
1
2
3
4
5
Right atrium
Right ventricle
• Although anatomically the heart consist of individual cells, the bands of muscle wind around the heart and work as a unit – forming a “functional syncytium” .– This allows the top
and bottom parts to contract in their own unique way.
Coordinating Contractions
Coordinating Contractions• The atrial muscle syncytium contracts as a single unit
to force blood down into the ventricles.• The syncytium of ventricular muscle starts contracting
at the apex (inferiorly), squeezing blood upward to exit the outflow tracts.
ANS Innervation
• Although the heart does not rely on outside nerves for its basic rhythm, there is abundant sympathetic and parasympathetic innervation which alters the rate and force of heart contractions.
ANS Innervation
• The action potential (AP) initiated by the SA node travels
through the conduction system to excite the “working”
contractile muscle fibers in the atria and ventricles.
• Unlike autorhythmic fibers, contractile fibers have a stable RMP
of –90mV.
– The AP propagates
throughout the heart
by opening and closing
Na+ and K+ channels.
Cardiac Muscle Action Potential
Depolarization Repolarization
Refractory period
Contraction
Membranepotential (mV) Rapid depolarization due to
Na+ inflow when voltage-gatedfast Na+ channels open
0.3 sec
+ 20
0
–20
–40
– 60
– 80
–100
11
Depolarization Repolarization
Refractory period
Contraction
Membranepotential (mV) Rapid depolarization due to
Na+ inflow when voltage-gatedfast Na+ channels open
Plateau (maintained depolarization) due to Ca2+ inflowwhen voltage-gated slow Ca2+ channels open andK+ outflow when some K+ channels open
0.3 sec
+ 20
0
–20
–40
– 60
– 80
–100
2
11
2
Depolarization Repolarization
Refractory period
Contraction
Membranepotential (mV)
Repolarization due to closureof Ca2+ channels and K+ outflowwhen additional voltage-gatedK+ channels open
Rapid depolarization due toNa+ inflow when voltage-gatedfast Na+ channels open
Plateau (maintained depolarization) due to Ca2+ inflowwhen voltage-gated slow Ca2+ channels open andK+ outflow when some K+ channels open
0.3 sec
+ 20
0
–20
–40
– 60
– 80
–100
2
1
3
1
2
3
Cardiac Muscle Action Potential
Cardiac Muscle Action Potential
• Unlike skeletal muscle, the refractory period in cardiac muscle
lasts longer than the contraction itself - another contraction
cannot begin until relaxation is well underway.
• For this reason, tetanus (maintained contraction) cannot occur
in cardiac muscle, leaving sufficient time between contractions
for the chambers to fill with blood.
• If heart muscle could undergo tetanus, blood flow would cease!
The Electrocardiogram• An ECG is a recording of the electrical changes
on the surface of the body resulting from the depolarization and repolarization of the myocardium.
• ECG recordings measure the presence or absence of certain waveforms (deflections), the size of the waves, and the time intervals of the cardiac cycle.– By measuring the ECG, we can quantify and
correlate, electrically, the mechanical activities of the heart.
The Electrocardiogram
1 Depolarization of atrialcontractile fibersproduces P wave
0.20
Seconds
Action potentialin SA node
P
1
Atrial systole(contraction)
Depolarization of atrialcontractile fibersproduces P wave
0.20Seconds
0.20
Seconds
Action potentialin SA node
P
P
2
1
Depolarization ofventricular contractilefibers produces QRScomplex
Atrial systole(contraction)
Depolarization of atrialcontractile fibersproduces P wave
0.2 0.40Seconds
0.20Seconds
0.20
Seconds
Action potentialin SA node
R
SQ
P
P
2
3
P
1
Ventricular systole(contraction)
Depolarization ofventricular contractilefibers produces QRScomplex
Atrial systole(contraction)
Depolarization of atrialcontractile fibersproduces P wave
0.2 0.40Seconds
0.2 0.40Seconds
0.20Seconds
0.20
Seconds
Action potentialin SA node
R
SQ
P
P
P
2
3
4
P
1
5Repolarization ofventricular contractilefibers produces Twave
Ventricular systole(contraction)
Depolarization ofventricular contractilefibers produces QRScomplex
Atrial systole(contraction)
Depolarization of atrialcontractile fibersproduces P wave
0.60.2 0.40Seconds
0.2 0.40Seconds
0.2 0.40Seconds
0.20Seconds
0.20
Seconds
Action potentialin SA node
R
SQ
P
P
P
PT
2
3
4
5
P
1
6Ventricular diastole(relaxation)
5Repolarization ofventricular contractilefibers produces Twave
Ventricular systole(contraction)
Depolarization ofventricular contractilefibers produces QRScomplex
Atrial systole(contraction)
Depolarization of atrialcontractile fibersproduces P wave
0.60.2 0.40 0.8
Seconds
0.60.2 0.40Seconds
0.2 0.40Seconds
0.2 0.40Seconds
0.20Seconds
0.20
Seconds
Action potentialin SA node
R
SQ
P
P
P
PT
P
2
3
4
5
6
P
• Blood Pressure is usually measured in the larger conducting
arteries where the high and low pulsations of the heart can be
detected – usually the brachial artery.
– Systolic BP is the higher pressure measured during left
ventricular systole when the
aortic valve is open.
– Diastolic BP is the lower pressure
measured during left ventricular
diastole when the valve is closed.
Blood Pressure
Blood Pressure• Normal BP varies by age, but is approximately 120 mm Hg
systolic over 80 mmHg diastolic in a healthy young adult ( in
females, the pressures are often 8–10 mm Hg less.)
• It is often best to refer to the blood pressure as a single number,
called the mean arterial pressure (MAP) .
– MAP is roughly 1/3 of the way between the diastolic and
systolic BP. It is defined as 1/3 (systolic BP – diastolic BP) +
diastolic BP.
Blood Pressure• In a person with a BP of 120/80 mm Hg, MAP = 1/3 (120-80) +
80 = 93.3 mm Hg.
• In the smaller arterioles,
capillaries, and veins,
the BP pulsations are not
detectable, and only a
mean BP is measurable
(see the purple and blue
areas of this figure).
Cardiac Cycle• The cardiac cycle includes all events associated
with one heartbeat, including diastole (relaxation phase) and systole (contraction phase) of both the atria and the ventricles.
• In each cycle, atria and ventricles alternately contract and relax.– During atrial systole, the ventricles are relaxed.– During ventricle systole, the atria are relaxed.
Cardiac Cycle• Since ventricular function matters most to the body, the two
principal events of the cycle for us to understand are ventricular
filling (during ventricular diastole), and ventricular ejection
(during ventricular systole).
– The blood pressure that we measure in the arm is a reflection
of the pressure developed by the left ventricle, before and
after left ventricular systole.
– Pulmonary blood pressure is a result of right ventricular
function, but is not easily measured.
Cardiac Cycle
Valves
AV SL Outflow
Ventricular
diastoleOpen Closed
Atrial
systole
Ventricular
systoleClosed Open
Early atrial
diastole
Ventricular
diastoleOpen Closed
Late atrial
diastole
Cardiac Cycle• During the cardiac cycle, all 4 of the heart valves have a chance
to open and close. Listening (usually with a stethoscope) to the
sounds the heart makes is called auscultation.
• Valve opening is usually
silent. The “lubb dupp”
we associate with
heart auscultation is
produced by valve closure (in pairs – see p. 740 left side).
Cardiac Cycle
Cardiac Cycle• The average time required to complete the cardiac
cycle is usually less than one second (about 0.8
seconds at a heart rate of 75 beats/minute).
– 0.1 seconds – atria contract (atrial “kick”), ventricles are
relaxed
– 0.3 seconds – atria relax, ventricles contract
– 0.4 seconds – relaxation period for all chambers, allowing
passive filling. When heart rate increases, it’s this relaxation
period that decreases the most.
Cardiac Output
• The stroke volume (SV) is the volume of blood ejected from the left (or right) ventricle every beat. The cardiac output (CO) is the SV x heart rate (HR).– In a resting male, CO = 70mL/beat x 75 beats/min =
5.25L/min.• On average, a person’s entire blood volume
flows through the pulmonary and systemic circuits each minute.
Cardiac Output• The cardiac reserve is the difference between
the CO at rest and the maximum CO the heart can generate.– Average cardiac reserve is 4-5 times resting value.
• Exercise draws upon the cardiac reserve to meet the body’s increased physiological demands and maintain homeostasis.
Cardiac Output• The cardiac output is affected by changes in SV, heart rate, or
both.
• There are 3 important factors that affect SV
– The amount of ventricular filling before contraction (called
the preload)
– The contractility of the ventricle
– The resistance in the blood vessels (aorta) or valves (aortic
valve, when damaged) the heart is pumping into (called the
afterload)
Cardiac Output• The more the heart muscle is stretched (filled) before
contraction (preload), the more forcefully the heart will
contract. This phenomenon is known as Starling’s Law of the
heart.
– Stimulation of the sympathetic
nervous system during
exercise increases venous
return, stretches the heart
muscle, and increases CO.
Cardiac Output
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