Part of the cardiac cycle when a heart chamber contracts
The cardiac cycle at the point of beginning a ventricular systole, or contraction: 1) newly oxygenated blood (red arrow) in the left ventricle begins pulsing through the
aortic valve
to supply all body systems; 2) oxygen-depleted blood (blue arrow) in the right ventricle begins pulsing through the
pulmonic (pulmonary) valve
en route to the lungs for reoxygenation.
Systole
(
SIST
-?-lee
) is the part of the
cardiac cycle
during which some
chambers
of the
heart
contract after refilling with blood.
[1]
Etymology
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]
The term originates, via
Neo-Latin
, from
Ancient Greek
συστολ?
(
sustol?
), from
συστ?λλειν
(
sustellein
'to contract'; from
σ?ν
sun
'together' +
στ?λλειν
stellein
'to send'), and is similar to the use of the English term
to squeeze
.
Terminology, general explanation
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Electrical waves track a systole (a contraction) of the heart. The end-point of the
P wave
depolarization is the start-point of the atrial stage of systole. The ventricular stage of systole begins at the R peak of the
QRS wave complex
; the T wave indicates the end of ventricular contraction, after which ventricular relaxation (ventricular diastole) begins.
[2]
The mammalian
heart
has four chambers: the left
atrium
above the left
ventricle
(lighter pink, see graphic), which two are connected through the
mitral (or bicuspid) valve
; and the right atrium above the right ventricle (lighter blue), connected through the
tricuspid valve
. The atria are the receiving blood chambers for the circulation of blood and the ventricles are the discharging chambers.
In late ventricular
diastole
, the atrial chambers contract and send blood to the ventricles. This flow fills the ventricles with blood, and the resulting pressure closes the valves to the atria. The ventricles now perform
isovolumetric contraction
, which is contraction while all valves are closed. This contraction ends the first stage of systole. The second stage proceeds immediately, pumping oxygenated blood from the left ventricle through the aortic valve and
aorta
to all body systems, and simultaneously pumping oxygen-poor blood from the right ventricle through the
pulmonic valve
and
pulmonary artery
to the
lungs
. Thus, the pairs of chambers (upper atria and lower ventricles) contract in alternating sequence to each other. First, atrial contraction feeds blood into the ventricles, then ventricular contraction pumps blood out of the heart to the body systems, including the lungs for resupply of oxygen.
Cardiac systole is the contraction of the
cardiac muscle
in response to an electrochemical stimulus to the heart's cells (
cardiomyocytes
).
Cardiac output
is the volume of blood pumped by the ventricles in one minute. The
ejection fraction
is the volume of blood pumped divided by the total volume of blood in the left ventricle.
[3]
Types of systole
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Atrial systole
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]
The cardiac cycle at beginning of atrial systole: The left (red) and right (blue) ventricles begin to fill during ventricular diastole. Then, after tracing the
P wave
of the
ECG
, the two atria begin contracting (systole), pulsing blood under pressure into the ventricles.
Atrial systole occurs late in
ventricular
diastole
and represents the contraction of
myocardium
of the left and right
atria
. The sharp decrease in ventricular pressure that occurs during ventricular diastole allows the
atrioventricular valves
(or
mitral
and
tricuspid
valves) to open and causes the contents of the atria to empty into the ventricles. The atrioventricular valves remain open while the aortic and pulmonary valves remain closed because the pressure gradient between the atrium and ventricle is preserved during late ventricular diastole. Atrial contraction confers a minor-fraction addition to ventricular filling, but becomes significant in
left ventricular hypertrophy
, or thickening of the heart wall, as the ventricle does not fully relax during its diastole. Loss of normal electrical conduction in the heart?as seen during
atrial fibrillation
,
atrial flutter
, and
complete heart block
?may eliminate atrial systole completely.
Contraction of the atria follows depolarization, represented by the
P wave
of the ECG. As both atrial chambers contract?from the superior region of the atria toward the atrioventricular septum?pressure rises within the atria and blood is pumped into the ventricles through the open atrioventricular valves. At the start of atrial systole, during ventricular diastole, the ventricles are normally filled to about 70?80 percent of capacity by inflow from the atria. Atrial contraction also referred to as the "atrial kick," contributes the remaining 20?30 percent of ventricular filling. Atrial systole lasts approximately 100 ms and ends prior to ventricular systole, as the atrial muscle returns to diastole.
[4]
The two ventricles are isolated electrically and
histologically
(tissue-wise) from the two atrial chambers by electrically impermeable collagen layers of connective tissue known as the
cardiac skeleton
. The cardiac skeleton is made of dense connective tissue which gives structure to the heart by forming the
atrioventricular septum
?which separates the atria from the ventricles?and the fibrous rings which serve as bases for the four heart valves.
[5]
Collagen extensions from the valve rings seal and limit electrical activity of the atria from influencing electrical pathways that cross the ventricles. These electrical pathways contain the
sinoatrial node
, the
atrioventricular node
, and the
Purkinje fibers
. (Exceptions such as accessory pathways may occur in this firewall between atrial and ventricular electrical influence but are rare.)
Cardiac rate control via pharmacology is common today; for example, the therapeutic use of digoxin,
beta adrenoceptor antagonists
, or
calcium channel blockers
are important historical interventions in this condition. Notably, individuals prone to
hypercoagulability
(abnormality of
blood coagulation
) are at decided risk of
blood clotting
, a very serious pathology requiring therapy for life with an
anticoagulant
if it cannot be corrected.
Right and left atrial systoles
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The atrial chambers each contains one valve: the
tricuspid valve
in the right atrium opens into the right ventricle, and the
mitral (or bicuspid) valve
in the left atrium opens into the left ventricle. Both valves are pressed open during the late stages of ventricular diastole; see Wiggers diagram at the P/QRS phase (at right margin). Then the contractions of atrial systole cause the right ventricle to fill with oxygen-depleted blood through the tricuspid valve. When the right atrium is emptied?or prematurely closed?right atrial systole ends, and this stage signals the end of
ventricular diastole
and the beginning of
ventricular systole
(see Wiggers diagram). The time variable for the right systolic cycle is measured from (tricuspid) valve-open to valve-closed.
The contractions of atrial systole fill the left ventricle with oxygen-enriched blood through the mitral valve; when the left atrium is emptied or closed, left atrial systole is ended and ventricular systole is about to begin. The time variable for the left systolic cycle is measured from (mitral) valve-open to valve-closed.
Atrial fibrillation
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Atrial fibrillation
represents a common electrical malady in the heart that appears during the time interval of atrial systole (see figure at right margin). Theory suggests that an
ectopic focus
, usually situated within the pulmonary trunks, competes with the
sinoatrial node
for electrical control of the atrial chambers and thereby diminishes the performance of the atrial myocardium, or atrial heart muscle. The ordered,
sinoatrial
control of atrial electrical activity is disrupted, causing the loss of coordinated generation of pressure in the two atrial chambers. Atrial fibrillation represents an electrically disordered but well perfused atrial mass working (in an uncoordinated fashion) with a (comparatively) electrically healthy ventricular systole.
The compromised load caused by atrial fibrillation detracts from the overall performance of the heart, but the ventricles continue to work as an effective pump. Given this pathology, the
ejection fraction
may deteriorate by ten to thirty percent. Uncorrected atrial fibrillation can lead to heart rates approaching 200 beats per minute (bpm). If this rate can be slowed to a normal range, say about 80 bpm, the resultant longer fill-time within the cardiac cycle restores or improves the pumping capability of the heart. The labored breathing, for example, of individuals with uncontrolled atrial fibrillation, can often be returned to normal by (electrical or medical)
cardioversion
.
Ventricular systole and Wiggers diagram
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]
A
Wiggers diagram
, showing various events during systole (here primarily displayed as
ventricular systole
, or
ventricular contraction
). The very short interval (about 0.03 second) of isovolumetric, or fixed-volume, contraction begins (see upper left) at the R peak of the QRS complex on the electrocardiogram graph-line. + Ejection phase begins immediately after isovolumetric contraction?ventricular volume (red graph-line) begins to decrease as ventricular pressure (light blue graph-line) continues to increase; then pressure drops as it enters diastole.
A
Wiggers diagram
of ventricular systole graphically depicts the sequence of contractions by the myocardium of the two
ventricles
. Ventricular systole induces
self-contraction
such that pressure in both left and right ventricles rises to a level above that in the two atrial chambers, thereby closing the tricuspid and mitral valves?which are prevented from inverting by the
chordae tendineae
and the
papillary muscles
. Now ventricular pressure continues to rise in
isovolumetric, or fixed-volume, contraction
phase until maximal pressure (dP/dt = 0) occurs, causing the pulmonary and aortic valves to open in
ejection phase
. In ejection phase, blood flows from the two ventricles down its pressure gradient?that is, 'down' from higher pressure to lower pressure?into (and through) the
aorta
and the
pulmonary trunk
respectively. Notably, cardiac muscle
perfusion
through the heart's coronary vessels does not happen during ventricular systole; rather, it occurs during ventricular diastole.
Ventricular systole is the origin of the
pulse
.
Right and left ventricular systoles
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The
pulmonary (or pulmonic) valve
in the
right ventricle
opens into the
pulmonary trunk
, also known as the pulmonary artery, which divides twice to connect to each of the left and right lungs. In the
left ventricle
, the aortic valve opens into the aorta which divides and re-divides into the several branch arteries that connect to all body organs and systems except the lungs.
By its contractions, right ventricular (RV) systole pulses oxygen-depleted blood through the pulmonary valve through the pulmonary arteries to the lungs, providing
pulmonary circulation
; simultaneously, left ventricular (LV) systole pumps blood through the aortic valve, the aorta, and all the arteries to provide
systemic circulation
of oxygenated blood to all body systems. The left ventricular systole enables
blood pressure
to be routinely measured in the larger arteries of the left ventricle of the heart.
LV systole is volumetrically defined as the
left ventricular ejection fraction
(LVEF). Similarly, RV systole is defined as the
right ventricular ejection fraction
(RVEF). Higher than normal RVEF is indicative of
pulmonary hypertension
. The time variables of the ventricular systoles are: right ventricle, pulmonary valve-open to valve-closed; left ventricle, aortic valve-open to valve-closed.
Electrical systole
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The
sinoatrial node
(S-A Node) is the heart's natural
pacemaker
, issuing electrical signaling that travels through the heart muscle, causing it to contract repeatedly in cycle. It is situated at the top of the
right atrium
adjacent to the junction with the superior vena cava.
[6]
The S-A Node is a pale yellow structure. For humans, it is approximately 25 mm long, 3?4 mm wide and 2 mm thick. It contains two types of cells: (a) the small, round P
cells
which have very few
organelles and myofibrils,
and (b
)
the slender elongated
transitional cells
, which are intermediate in appearance between the P and the ordinary myocardial cells.
[7]
Intact, the SA node provides continual electrical discharge known as
sinus rhythm
through the atrial mass, the signals of which then coalesce at the
atrioventricular node
, there to be organized to provide a rhythmic electrical pulse into and across the ventricles through sodium-, potassium- or calcium-gated
ion channels
.
The continual rhythmic discharge generates a wavelike movement of electrical ripples that stimulate the smooth muscles of the myocardium and cause rhythmic contractions to progress from top to bottom of the heart. As the pulse moves out of the (upper) atria into the (lower) ventricles, it is distributed throughout a muscular network to cause systolic contraction of both ventricular chambers simultaneously. The actual pace of the cycle?just how fast or slowly the heart beats?is cued by messages from the brain, reflecting the brain's responses to conditions of the body, such as pain, emotional stress, level of activity, and to ambient conditions including external temperature, time of day, etc.
[8]
Mechanical systole
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Electrical systole opens voltage-gated sodium, potassium and calcium channels in cells of myocardium tissue. Subsequently, a rise in intracellular calcium triggers the interaction of
actin
and
myosin
in the presence of
ATP
which generates mechanical force in the cells in the form of muscular contraction, or mechanical systole. The contractions generate intra-ventricular pressure, which is increased until it exceeds the external, residual pressures in the adjacent trunks of both the
pulmonary artery
and the
aorta
; this stage, in turn, causes the
pulmonary
and
aortic
valves to open. Blood is then ejected from the two ventricles, pulsing into both the
pulmonic
and
aortic
circulation systems.
[9]
Mechanical systole causes the
pulse
, which itself is readily palpated (felt) or seen at several points on the body, enabling universally adopted methods?by touch or by eye?for observing systolic
blood pressure
.
The mechanical forces of systole cause rotation of the muscle mass around the long and short axes, a process that can be observed as a "wringing" of the ventricles.
Physiological mechanism
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Systole of the heart is initiated by
electrically excitable cells
situated in the
sinoatrial node
. These cells are activated spontaneously by
depolarization
of the electrical potential across their cell membranes, which causes
voltage-gated calcium channels
on the cell membrane to open and allow
calcium ions
to pass through into the
sarcoplasm
(cytoplasm) of cardiac muscle cells. Calcium ions bind to
molecular receptors
on the
sarcoplasmic reticulum (see graphic)
, which causes a
flux
(flow) of calcium ions into the
sarcoplasm
.
Calcium ions bind to
troponin C
, causing a
conformational (i.e., structural) change
in the troponin-tropomyosin
protein complex
, causing the
myosin head
(binding) sites on
F-actin filamentous proteins
to be exposed, which causes
muscle contraction
to occur.
The
cardiac action potential
spreads
distally
(or outwardly) to the small branches of the Purkinje tree via the flux of cations through
gap junctions
that connect the sarcoplasms of adjacent myocytes.
The electrical activity of ventricular systole is coordinated by the
atrioventricular node
, which is a discrete collection of cells that receives electrical stimulation from the left and right atria and can provide an intrinsic (albeit slower) heart pacemaker activity. The cardiac action potential is propagated down electrical pathways through the
bundle of His
to the
Purkinje fibres
; this electrical flux causes coordinated depolarisation and excitation-contraction coupling from the
apex of the heart
up to the roots of the great vessels.
Clinical notation
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When blood pressure is stated for medical purposes, it is usually written with the systolic and diastolic pressures separated by a
slash
, for example, 120/80
mmHg
. This clinical notation is not a mathematical figure for a fraction or ratio, nor a display of a numerator over a denominator. Rather, it is a medical notation showing the two clinically significant pressures involved (systole followed by diastole). It is often shown followed by a third number, the value of the
heart rate
(in beats per minute), which typically is measured jointly with blood pressure readings.
Pathology
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Systolic malfunction.
See also
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References
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]
- ^
Simmers, Louise (2004).
Introduction to Health Science Technology
. Australia: Thomson/Delmar Learning. p. 169.
ISBN
9781401811280
.
- ^
Topol, Eric J (2000).
Cleveland Clinic Heart Book
. New York: Hyperion. pp.
134?35
.
ISBN
0-7868-6495-8
.
- ^
Lang RM, Bierig M, Devereux RB, et al. (March 2006).
"Recommendations for chamber quantification"
.
Eur J Echocardiogr
.
7
(2): 79?108.
doi
:
10.1016/j.euje.2005.12.014
.
PMID
16458610
.
- ^
Betts, J. Gordon (2013).
Anatomy & physiology
. pp. 787?846.
ISBN
978-1938168130
. Retrieved
11 August
2014
.
- ^
Pocock, Gillian (2006).
Human Physiology
. Oxford University Press. p. 264.
ISBN
978-0-19-856878-0
.
- ^
Pocock, Gillian (2006).
Human Physiology
(Third ed.). Oxford University Press. p. 266.
ISBN
978-0-19-856878-0
.
- ^
Fung, Y. C. (2010).
Biomechanics : circulation
.
ISBN
9781441928429
.
OCLC
752495251
.
- ^
Topol, Eric J (2000).
Cleveland Clinic Heart Book
. New York: Hyperion. pp.
7?8
.
ISBN
0-7868-6495-8
.
- ^
Topol, Eric J (2000).
Cleveland Clinic Heart Book
. New York: Hyperion. pp.
8?9, 110?111
.
ISBN
0-7868-6495-8
.
External links
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]