CARDIAC CYCLE
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Transcript CARDIAC CYCLE
CARDIAC CYCLE
DR RAKESH JAIN
SR Cardiology
Govt. Medical College, Calicut.
Cardiac Cycle
Def: The cardiac events that occur from
beginning of one heart beat to the beginning
of the next.
first assembled by Lewis in 1920 but first
conceived by Wiggers in 1915
Atria act as PRIMER PUMPS for ventricles &
ventricles provide major source of power for
moving the blood through the vascular
system.
Initiated by spontaneous generation of AP in
SA node (located in the superior lateral wall of the right atrium
near the opening of the superior vena cava)
Electrical System: Brief
Action potentials originating
in the sinus node travel to
AV node (1m/s) in 0.03 sec.
1. AV nodal delay of 0.09 sec before the impulse
enters the penetrating portion of the A-V bundle
2. A final delay of another 0.04 sec occurs mainly in
this penetrating A-V bundle
total delay in the A-V nodal and A-V bundle
system is about 0.13 sec
A total delay of 0.16 sec occurs before the excitatory
signal finally reaches the contracting muscle of the
ventricles from its origin in sinus node.
Delay in AV node (0.13sec)
Why delay?
Diminished numbers of gap junctions Between successive
cells in the conducting pathways.
Significance?
Delay allows time for the atria to empty their blood into the
ventricles before ventricular contraction begins
Rapid Transmission in the Purkinje System
(1.5 to 4.0 m/sec)
i.e.
• About 6x that in ventricular muscle
• About 150x that in A-V nodal fibers
allowing almost instantaneous transmission
of the cardiac impulse throughout the
ventricular muscle
(B/c of very high level of permeability of the gap junctions)
Summary of Cardiac Impulse
Transmission
Mechanical Phase
Cardiac cycle – basically describes…
1.
2.
3.
Pressure
Volume, and
Flow phenomenon
in ventricles as a function of time
Basics
1 Beat = 0.8 sec (800 msec)
Systole = 0.3 sec
Diastole = 0.5 sec
In tachycardia, Diastolic phase decreases more than
systolic phase
Phases of cardiac cycle
LV Contraction
Isovolumic contraction (b)
Maximal ejection (c)
LV Relaxation
Start of relaxation and reduced ejection (d)
Isovolumic relaxation (e)
LV Filling
Rapid phase (f)
Slow filling (diastasis) (g)
Atrial systole or booster (a)
Time Intervals
Total ventricular systole
0.3 sec
Isovolumic contraction (b)
0.05 sec (0.015sec for RV)
Maximal ejection (c)
0.1 sec
Reduced ejection (d)
0.15 sec
Total ventricular diastole
0.5 sec
Isovolumic relaxation (e)
0.1 sec
Rapid filling phase (f)
0.1 sec
Slow filling (diastasis) (g)
0.2 sec
Atrial systole or booster (a) 0.1 sec
GRAND TOTAL (Syst+Diast) = 0.8 sec
Physiologic Versus Cardiologic Systole and
Diastole
PHYSIOLOGIC
SYSTOLE
Isovolumic
contraction
Maximal
ejection
PHYSIOLOGIC
DIASTOLE
Reduced
ejection
Isovolumic
relaxation
Filling phases
CARDIOLOGIC
SYSTOLE
From M1 to A2,
including:
Major part of
isovolumic contraction
Maximal ejection
Reduced ejection
CARDIOLOGIC
DIASTOLE
20msec
A2-M1 interval
(filling phases included)
Physiological systole
cardiologic systole, demarcated by heart
sounds rather than by physiologic events, starts
fractionally later than physiologic systole and
ends significantly later.
Cardiologic systole> physiologic systole
Description of Cardiac cycle phases
1.
2.
3.
4.
Pressure & Volume events
ECG correlation
Heart sounds
Clinical significance
Atrial Systole
A-V Valves Open; Semilunar Valves Closed
Blood normally flows
continually from great
veins into atria
80% flows directly thr
atria into ventricle
before the atria
contracts.
20% of filling of
ventricles – atrial
contraction
Atrial contraction is
completed before the
ventricle begins to
contract.
Atrial contraction normally accounts for about
10%-15% of LV filling at rest, however, At
higher heart rates, atrial contraction may
account for up to 40% of LV filling referred to
as the "atrial kick”
The atrial contribution to ventricular filling
varies inversely with duration of ventricular
diastole and directly with atrial contractility
Atrial Systole
Pressures & Volumes
‘ a ‘ wave – atrial contraction,
when atrial pressure rises.
Atrial pressure drops when
the atria stop contracting.
After atrial contraction is complete
LVEDV typically about 120 ml (preload)
End-diastolic pressures of
LV = 8-12 mmHg and
RV = 3-6 mmHg
AV valves floats upward (pre-position)
Abnormalities of “a” wave
Elevated a wave
Tricuspid stenosis
Decreased ventricular compliance (ventricular failure, pulmonic valve
stenosis, or pulmonary hypertension)
Cannon a wave
Atrial-ventricular asynchrony (atria contract against a closed tricuspid valve)
complete heart block, following premature ventricular contraction,
during ventricular tachycardia, with ventricular pacemaker
Absent a wave
Atrial fibrillation or atrial standstill
Atrial flutter
Why blood does not flow back in to SVC/PV
while atria contracting, even though no valve
in between?
Wave of contraction through the atria moves
toward the AV valve thereby having a
"milking effect."
Inertial effects of the venous return.
Atrial Systole
ECG
p wave – atrial depolarization
impulse from SA node results in depolarization &
contraction of atria ( Rt before Lt )
PR segment – isoelectric line as depolarization
proceeds to AV node.
This brief pause before contraction allows the
ventricles to fill completely with blood.
Atrial Systole
Heart Sounds
S4 (atrial or presystolic gallop) - atrial emptying after forcible
atrial contraction.
appears at 0.04 s after the P wave (late diastolic)
lasts 0.04-0.10 s
Caused by vibration of ventricular wall during rapid
atrium emptying into non compliant ventricle
Causes of S4
Physiological;
>60yrs (Recordable, not audible)
Pathological;
All causes of concentric LV/RV hypertrophy
Coronary artery disease
Acute regurgitant lesions
An easily audible S4 at any age is generally abnormal.
Clinical Facts about S4
In contrast to S3, which may mean ventricular
failure, the presence of S4 does not indicates heart
failure. It only signify “hardworking ventricle”.
The presence of S4 correlate with a gradient of at
least 50mmHg across LVOT in suspected LVOT
obstruction.
(This correlation is not applicable in HCM)
In setting of MI, an audible S4 indicates that at least
10% of myocardium is at jeopardy.
In presence of Shock, S4 indicates that hypovolemia
is unlikely as PCWP will be >18mmHg.
S4 can be heard when RVEDP >12mmHg on Rt or
LVEDP > 15mmHg on Lt side. If EDP is very high i.e.
>25 mmHg, S4 may be absent b/c of insufficient
atrial functions.
JVP: x descent
Prominent x descent
1
2
3
Cardiac tamponade
Constrictive pericarditis
Right ventricular ischemia with preservation of atrial
contractility
Blunted x descent
1
2
Atrial fibrillation
Right atrial ischemia
Beginning of Ven.Systole
Isovolumetric Contraction
All Valves Closed
Isovolumetric Contraction
Pressure & Volume Changes
The AV valves close when the
pressure in the ventricles (red)
exceeds the pressure in the
atria (yellow).
As the ventricles contract
isovolumetrically -- their volume
does not change (white) -- the
pressure inside increases,
approaching the pressure in the
aorta and pulmonary arteries
(green).
JVP: c wave- d/t Right
ventricular contraction pushes
the tricuspid valve into the
atrium and increases atrial
pressure, creating a small wave
into the jugular vein. It is
normally simultaneous with the
carotid pulse.
Ventricular chamber geometry changes considerably as the
heart becomes more spheroid in shape; circumference
increases and atrial base-to-apex length decreases.
Early in this phase, the rate of pressure development becomes
maximal. This is referred to as maximal dP/dt.
Ventricular pressure increases rapidly
LV ~10mmHg to ~ 80mmHg (~Aortic pressure)
RV ~4 mmHg to ~15mmHg (~Pulmonary A pressure)
At this point, semilunar (aortic and pulmonary) valves open against the
pressures in the aorta and pulmonary artery
LV Torsion
left-handed helix in subepicardium
right-handed helix in subendocardium
Figure: Schematic Drawing of LV Torsion
The image on the left shows the myofiber directions. Solid lines epicardial region; dashed
lines endocardial region. The image on the right shows untwisting.
ED end-diastole; ES end-systole; LV left ventricle.
(J Am Coll Cardiol Img 2009;2:648–55)
Isovolumetric Contraction
ECG
The QRS complex is due to ventricular
depolarization, and it marks the beginning of
ventricular systole.
Isovolumetric Contraction
Heart Sounds
S1 is d/t closure and after
vibrations of AV Valves. (M1
occurs with a definite albeit 20
msec delay after the LV-LA
pressure crossover.)
S1 is normally split (~0.04 sec)
because mitral valve closure
precedes tricuspid closure.
(Heard in only 40% of normal individuals)
S1 heart sound
low pitch and relatively long-lasting
lasts ~ 0.12-0.15 sec
frequency ~ 30-100 Hz
appears 0.02 – 0.04 sec after the
beginning of the QRS complex
Some Clinical facts about S1
S1 is a relatively prolonged, low frequency
sound, best heard at apex.
Normally split of S1 (~40%)is heard only at
tricuspid area.(As tricuspid component is
heard only here.)
If S1 is equal to or higher in intensity than S2
at base, S1 is considered accentuated.
Variable intensity of S1 and jugular venous pulse are
highly specific and sensitive in the diagnosis of
ventriculoatrial dissociation during VT, and is helpful
in distinguishing it from supraventricular tachycardia
with aberration.
Value of physical signs in the diagnosis of ventricular tachycardia. C J Garratt, M J
Griffith, G Young, N Curzen, S Brecker, A F Rickards and A J Camm, Circulation.
1994;90:3103-3107
Causes of
Loud S1
1.
2.
3.
4.
5.
6.
7.
Exercise
Emotinal excitibility
Mitral stenosis
Hyperkinetic circulation
Atrial septal defect
Sinus tachycardia
Short P-R interval
Soft S1
1.
2.
3.
4.
5.
6.
7.
8.
9.
Sinus tachycardia
Mitral regurgitation
Severe AR
Ventricular aneurysm
Acute MI
Myocarditis
Cardiomyopathy
Prolonged P-R interval
Calcific MS
Ejection
Aortic and Pulmonic Valves Open; AV Valves Remain Closed
The Semilunar valves ( aortic ,
pulmonary ) open at the beginning of
this phase.
Two Phases
• Rapid ejection - 70% of the blood
ejected during the first 1/3 of ejection
• Slow ejection - remaining 30% of
the blood emptying occurs during
the latter 2/3 of ejection
Rapid Ejection
Pressure & Volume Changes
When ventricles continue
to contract , pressure in
ventricles exceed that of
in aorta & pul arteries &
then semilunar valves
open, blood is pumped
out of ventricles &
Ventricular vol decreases
rapidly.
Ventricular contraction: RV v/s LV
Rapid Ejection
ECG & Heart Sounds
In rapid ejection part of the
ejection phase there no
specific ECG changes / heart
sounds heard.
Slow Ejection
Aortic and Pulmonic Valves Open; AV Valves
Remain Closed
Blood flow from the left
ventricle to the aorta
rapidly diminishes but
is maintained by aortic
recoil, the “Windkessel
effect “
At the end of ejection,
the semilunar valves
close. This marks the
end of ventricular
systole mechanically.
Slow Ejection
ECG & Heart Sounds
T wave – slightly
before the end of
ventricular
contraction
it is d/t ventricular
repolarization
heart sounds : none
Beginning of Diastole
Isovolumetric relaxation
All Valves Closed
At the end of systole, ventricular relaxation
begins, allowing intraventricular pressures to
decrease rapidly (LV from 100mmHg to
20mmHg & RV from 15mmHg to 0mmHg),
aortic and pulmonic valves abruptly close (aortic
precedes pulmonic) causing the second heart
sound (S2)
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
Isovolumetric relaxation
Volumes remain constant because all valves
are closed
volume of blood that remains in a ventricle is
called the end-systolic volume (LV ~50ml).
pressure & volume of ventricle are low in this
phase .
Isovolumetric relaxation
Throughout this and the
previous two phases, the
atrium in diastole has been
filling with blood on top of
the closed AV valve,
causing atrial pressure to
rise gradually
JVP - "v" wave occurs
toward end of ventricular
contraction – results from
slow flow of blood into atria
from veins while AV valves
are closed .
Isovolumetric relaxation
ECG & Heart Sounds
ECG : no deflections
Heart Sounds : S2 is
heard when the
semilunar vlaves
close.
A2 is heard prior to
P2 as Aortic valve
closes prior to
pulmonary valve.
Why A2 occurs prior to P2 ?
“Hangout interval” is longer for pulmonary side
(~80msec),compared to aortic side (~30msec).
Hangout interval is the time interval from crossover of
pressures (ventricle with their respective vessel) to the
actual occurrence of sound.
Due to lower pressure and higher distensibility,
pulmonary artery having longer hangout interval
causing delayed PV closure and P2.
S2 heart sound
Appears in the terminal period of the T
wave
lasts 0.08 – 0.12s
Some clinical facts about S2
Normal split: Two components heard during
inspiration and is single sound during expiration.
(A2-P2 ~20- 50 msec in inspiration)
Clinically split is defined as wide, if it is heard well in
standing position, in expiration (normally not heard as the
split is 15 msec, which can not be heard by human ears)
Single S2: absence of audible split in either phase of
respiration.
Fixed split: two components fails to move
with respiration.
Reverse split: Inaudible split during
inspiration and audible split during expiration.
(recognized by wider split in expiration)
Common causes of wide split S2
RBBB
Sev PAH
ASD
Idiopathic dilatation of pul artery
Sev right heart failure
Moderate to severe PS
Severe MR
Normal variant
Common causes of wide fixed split S2
ASD
All causes of wide split with associated
severe right ventricular failure.
Common causes of single S2
Truncus arteriosus
Pulmonary atresia
Aortic atresia
TGA
AS, PS
Single loud P2 in extreme PAH
Causes of reverse split S2
LBBB
RV pacing
RV ectopy
Severe AS
Acute MI
WPW type B
Severe TR
Aneurysm of ascending aorta
Severe systemic hypertension
JVP: V wave
Elevated v wave
1
2
3
Tricuspid regurgitation
Right ventricular heart failure
Reduced atrial compliance (restrictive myopathy)
a wave equal to v wave
1
2
3
Tamponade
Constrictive pericardial disease
Hypervolemia
Rapid Inflow ( Rapid Ven. Filling)
A-V Valves Open
Once AV valves are open the
blood that has accumulated
in atria flows into the
ventricle.
Rapid Inflow
Volume changes
Despite the inflow of blood from
the atria, intraventricular
pressure continues to briefly fall
because the ventricles are still
undergoing relaxation
JVP: Seen as y-descent.
Rapid Inflow ( Rapid Ven. Filling)
ECG & Heart Sounds
ECG : no deflections
Heart sounds : S3 is heard,
lasts 0.02-0.04 sec
(represent tensing of chordae
tendineae and AV ring during
ventricular relaxation and filling)
Whatever the mechanism, a
sudden inherent limitation in
the long axis filling movement
of the LV is consistently
observed.
Clinical facts about S3
In presence of HF, S3 correlates well with
ventricular end diastolic pressure and is
usually >25mmHg on left side.
Right sided S3 correlate well with rapid y
descend in neck veins.
Normal A2-S3 interval is between 120-160
msec.
Correlates of S3
Anatomical
Dilated ventricle
Functional
Systolic dysfunction
(EF<40%)
Hemodynamics
LVEDP
Cardiac index
Symptoms
Doppler flow across AV
valve
>25 mmHg
<2 L/min/m2
Dyspnea, PND, Orthopnea
Tall E wave compare to A wave
Gallop rhythm
A gallop rhythm is a grouping of three heart sounds that
together sound like hoofs of a galloping horse.
Protodiastolic gallop or ventricular gallop or S3 gallop
addition of an S3 to the physiological S1 and S2 creates a
three-sound sequence, S1-S2-S3.
Presystolic gallop rhythm or atrial gallop
addition of an S4 to the physiological S1 and S2 creates a
three-sound sequence, S4-S1-S2.
(during tachycardia S4-S1 can fuse, producing a summation gallop )
Causes of S3
Physiological: Childrens & young adults <40 yrs (nearly 25%)
(Not heard in normal infants & adult >40 yrs.)
Pathological:
Ventricular failure
Hyperkinetic state (anemia, thyrotoxicosis, beri-beri)
MR, TR
AR, PR
Systemic AV fistula
JVP: y descent
Prominent y descent
1
2
3
Constrictive pericarditis
Restrictive myopathies
Tricuspid regurgitation
Blunted y descent
1
2
3
Tamponade
Right ventricular ischemia
Tricuspid stenosis
Diastasis
A-V Valves Open
remaining blood
which has
accumulated in atria
slowly flows into the
ventricle.
Diastasis
Volume changes
Ventricular volume increases
more slowly now. The
ventricles continue to fill
with blood until they are
nearly full.
Diastasis
ECG & Heart Sounds
ECG : no deflections
Heart Sounds : none
The Lewis or wiggers cycle, Guyton & Hall. Textbook of Medical Physiology, 11th Edition
Volumes
End diastolic vol
: During diastole, filling of
ventricle increases vol of each ventricle to
~ 110 -120 ml
Stroke Vol : amount of blood pumped out of
ventricle during systole. ~ 70 ml
End systolic vol : the remaining amount of
blood in ventricle after the systole. ~40 -50
ml
Pressure-Volume Loop
Pressure-volume loop of RV
is same as that of LV,
however the area is only 1/5th
of LV because pressures
are so much lower on right
RV v/s LV
Rt
•
•
•
Ventricular
Pressure wave 1/5th
dp/dt is less
Isovolumic contraction &
relaxation phases are
short.
Timing of Cardiac EVENTS
1. RA start contracting before LA
2. LV start contracting before RV
3. TV open before MV,
so RV filling start before LV.
4. RV peak pressure 1/5th of LV.
5. RV outflow velocity smooth
rise & fall, while Lt side initial
peak followed by quick fall.
The First cardiac catheterization
Cardiac catheterization was first attempted by Dr Werner
Forssmann in 1929, at the age of 25 yrs only, when he was a
resident in a hospital at Eberswalde, near Berlin. He was his own
subject. A fellow resident who agreed to pass the catheter, got
scared and abandoned the effort by the time the catheter reached
the axilla. Forssmann completed the task himself with radiographer
holding the mirror infront of screen. Forssmann catheterize his heart
safely nine times till he had no more peripheral veins left to try. But
this was not enough to convince the medical world about the safety
of the procedure. After being banished from academics, frustrated
Forssmann settled for medical practice in a small town.
It was extensive studies with catheterization by Dr Andre
Cournand & Dr Dickinson Richard Jr. and eventually the novel prize
for physiology & medicine was awarded jointly to Forssmann, Cournand
& Richard in 1956.
The history of cardiac catheterization illustrates what
reckless idealism of youth can achieve and the long time (here 27 yrs)
might take the world to realize the value of even something of great
significance.
References
1.
2.
3.
4.
5.
6.
Guyton and Hall Textbook of Medical Physiology, 11th Ed.
Arthur C. Guyton, John E. Hall.
Cardiovascular Physiology Concepts Second Edition, Lippincott
Williams & Wilkins, 2011
Clinical Methods in Cardiology By Soma Raju, Second Edition,
orient longman
Braunwald's Heart Disease: A Textbook of Cardiovascular
Medicine, ninth edition
Harrison's Principles of Internal Medicine, 19th edition,
McGraw-Hill Book Co
Understanding Medical Physiology: A Textbook for Medical
Students: By R.L. Bijlani, M.D., RL Bijlani MD SM DSc (Hon
Causa) FAMS, S. Manjunatha,4th edition
7.
Medical Physiology E-Book: By Walter F. Boron, Emile
L.Boulpaep, Second Edition
8.
Value of physical signs in the diagnosis of ventricular
tachycardia. C J Garratt, M J Griffith, G Young, N Curzen, S
Brecker, A F Rickards and A J Camm, Circulation.
1994;90:3103-3107
9.
Color Atlas of Physiology. Stefan Silbernagel, Agamemnon
Despopoulos. 6th Edition.
10. Jacc: cardiovascular imaging, Vol.2 No. 5, 2009. May 2009:
648-55.
QUIZ
1.
Which letter indicates the point in the
cardiac cycle that the mitral valve
opens?
A. A
B. B
C. C
D. D
2. In a normal cardiac cycle , true is
A. RA ejection precedes LA ejection
B. RV contraction starts before LV contraction
C. LV ejection starts before RV ejection
D. Pulmonary valve closes before aortic valve
3. Which letter in the image represents the
isovolumic 2.contraction of the left ventricle
in the heart?
A. F
B. B
C. H
D. D
4. Which of the following pairs is INCORRECT?
A. P wave: atrial depolarization
B. QRS complex: ventricular depolarization
C. T wave: ventricular repolarization
D. QT interval: Measure of duration of atrial action
potential
5. Isovolumic contraction phase correspond to
A. AV opening to AV Closure
B. MV closure to MV opening
C. MV closure to AV opening
D. AV opening to MV opening
6. Left ventricular end-diastolic volume is:
A. 30-50 mls
B. 50-70 mls
C. 70-120 mls
D. 120-150 mls
7. Prominent y descent in JVP seen in all except
A. Constrictive pericarditis
B. Restrictive cardiomyopathies
C. Tricuspid regurgitation
D. Cardiac temponade
8. All are true about S3 except
A. Right sided S3 correlate well with rapid y descend
in neck veins.
B. S3 normally heard in normal infants
C. S3 usually indicates systolic dysfunction
D. S3 correlates well with ventricular end diastolic
pressure usually >25mmHg on left side
9. Cardiac apex is palpable during which phase of
cardiac cycle
A. Isovolumic contraction phase
B. Isovolumic relaxation phase
C. Rapid ejection phase
D. Atrial systole phase
10. Sensitive & specific sign of ventricularterial
dissociation in VT are
A. Variable intensity of S1
B. Variable jugular venous pulse
C. Both A & B
D. None of the above
Answers
1.
Which letter indicates the point in the
cardiac cycle that the mitral valve
opens?
A. A
B. B
C. C
D. D
2. In a normal cardiac cycle , true is
A. RA ejection precedes LA ejection
B. RV contraction starts before LV contraction
C. LV ejection starts before RV ejection
D. Pulmonary valve closes before aortic valve
3. Which letter in the image represents the
isovolumic 2.contraction of the left ventricle
in the heart?
A. F
B. B
C. H
D. D
4. Which of the following pairs is INCORRECT?
A. P wave: atrial depolarization
B. QRS complex: ventricular depolarization
C. T wave: ventricular repolarization
D. QT interval: Measure of duration of atrial action
potential
5. Isovolumic contraction phase correspond to
A. AV opening to AV Closure
B. MV closure to MV opening
C. MV closure to AV opening
D. AV opening to MV opening
6. Left ventricular end-diastolic volume is:
A. 30-50 mls
B. 50-70 mls
C. 70-120 mls
D. 120-150 mls
7. Prominent y descent in JVP seen in all except
A. Constrictive pericarditis
B. Restrictive cardiomyopathies
C. Tricuspid regurgitation
D. Cardiac temponade
8. All are true about S3 except
A. Right sided S3 correlate well with rapid y descend
in neck veins.
B. S3 normally heard in normal infants
C. S3 usually indicates systolic dysfunction
D. S3 correlates well with ventricular end diastolic
pressure usually >25mmHg on left side
9. Cardiac apex is palpable during which phase of
cardiac cycle
A. Isovolumic contraction phase
B. Isovolumic relaxation phase
C. Rapid ejection phase
D. Atrial systole phase
10. Sensitive & specific sign of ventricularterial
dissociation in VT are
A. Variable intensity of S1
B. Variable jugular venous pulse
C. Both A & B
D. None of the above
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