Cardiac Output, Stroke volume, EDV, ESV, Ejection Fraction

CARDIAC OUTPUT is the amount of blood pumped
by each ventricle in one minute. It is the product of STROKE VOLUME – the
amount of blood pumped in one heartbeat, and HEART RATE – the number of beats in one
minute. An INcrease in either stroke volume or heart
rate results in INcreased cardiac output, and vice versa. For example, during physical exercises, the
heart beats faster to put out more blood in response to higher demand of the body. It is noteworthy that the ventricles do NOT
eject ALL the blood they contain in one beat. In a typical example, a ventricle is filled
with about 100ml of blood at the end of its load, but only 60ml is ejected during contraction. This corresponds to an EJECTION fraction of
60%. The 100ml is the end-DIASTOLIC volume, or
EDV. The 40ml that remains in the ventricle after
contraction is the end-SYSTOLIC volume, or ESV. The stroke volume equals EDV minus ESV, and
is dependent on 3 factors: contractility, preload, and afterload. Contractility refers to the force of the contraction
of the heart muscle. The more forceful the contraction, the more
blood it ejects. PRELOAD is RELATED to the end-diastolic volume. Preload, by definition, is the degree of STRETCH
of cardiac myocytes at the end of ventricular filling, but since this parameter is not readily
measurable in patients, EDV is used instead. This is because the stretch level of the wall
of a ventricle INcreases as it’s filled with more and more blood; just like a balloon
– the more air it contains, the more stretched it is. According to the Frank-Starling mechanism,
the greater the stretch, the greater the force of contraction. In the balloon analogy, the more inflated
the balloon, the more forceful it releases air when deflated. AFTERLOAD, on the other hand, is the RESISTANCE
that the ventricle must overcome to eject blood. Afterload includes 2 major components:
– Vascular pressure: The pressure in the left ventricle must be GREATER than the systemic
pressure for the aortic valve to open. Similarly, the pressure in the right ventricle
must exceed pulmonary pressure to open the pulmonary valve. In hypertension for example, higher vascular
pressures make it more difficult for the valves to open, resulting in a REDUCED amount of
ejected blood. – Damage to the valves, such as stenosis,
also presents higher resistance and leads to lower blood output.


  1. Thank you for breaking this down. It is easier to grasp the concept and apply it to my graduate course. Thank you!

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  4. if the stroke volume of heart increased with the cardiac output remaining the same the heart beat per minute will be??

  5. i just spent one hour trying to figure it out i was just about to give up when i decided to open youtube, thank god i did and thank you for this video!

  6. Your videos are very concise and very informative. Thank you for that. I would like to request you to explain effect of external pressures outside the heart on cardiac output curves ( externak pressures like cyclical changes of intraplueral pressure during respiration, breathing against a negative pressure, positive pressure breathing, opening the thoracic cage, cardiac tamponade)

  7. Just the fancy names make this concept so hard to understand. It is fucking simple. But everytime i reopen it i feel like i am stupid.

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