Cardiac Cycle

Question 1

Blood flow through the heart

Answer 1

1. venous return via great veins (SVC and IVC) into the right atrium
2. goes through the tricuspid valve
3. enters the right ventricle
4. goes through the pulmonary semilunar valve
5. enters the pulmonary arteries
6. lung circulation
7. pulmonary veins bring blood to the left atrium
8. goes through mitral (bicuspid) valve
9. enters the left ventricle
10. goes through the aortic semilunar valve
11. enters the aorta
12. systemic circulation

Question 2

The cardiac cycle can split into 4 steps. What are these steps?

Answer 2

• ventricular filling/atria contraction
• isovolumetric contraction
• ejection
• isovolumetric relaxation

Question 3

Describe phase 1, ventricular filling/atria contraction

Answer 3

• there is a higher pressure in the atria, as they have been filling up with blood.
• so, higher pressure in atria>ventricles
• pressure gradient means that the tricuspid and mitral valve open
• so, blood is going to move from atria into the ventricles
• at the end of ventricular filling, you get atrial contraction. this gives an extra oomph to filling the ventricles

Question 4

Describe phase 2, isovolumetric contraction

Answer 4

• so, higher pressure in ventricles > atria
• so, tricuspid and mitral valve close to prevent the backflow of blood
• this means we have a period of time where we have a closed ventricular chamber. nothing is going in, nothing is coming out
• walls of the ventricles start to contract. pressure in the ventricular chambers increases (in order to increase the pressure relative to the arteries)

Question 5

Describe phase 3, ejection

Answer 5

• higher pressure in ventricles > aorta and pulmonary artery
• ventricular chambers continue to contract, but as the pressure is greater than that of the aorta and pulmonary artery, the aortic valve and pulmonic valve open
• so, blood flows out of the heart via the arteries
• blood enters atria

Question 6

Describe phase 4, isovolumetric relaxation

Answer 6

• higher pressure in aorta and pulmonary artery > ventricles
• aortic and pulmonic valves close - so now we have a closed ventricle with not much blood in it. this is known as isovolumetric relaxation
• ventricles relaxes, expands, ready to receive
• blood is still returning to atria

Question 7

What is EDV?

Answer 7

End diastolic volume
When mitral valve closes
approx 120 ml

Question 8

What is ESV?

Answer 8

End systolic volume

amount of blood left in the chamber after ejection has occurred which is approx 40ml

Question 9

Describe left ventricular pressure changes

Answer 9

• during ventricular filling, pressure is very low
• as ventricle fills, pressure starts to increase
• arial systole causes more blood to enter ventricle.
• and so pressure in ventricles > atria
• so mitral valve closes - resulting in a closed ventricle - nothing going in or out
• then isovolumetric contraction occurs - causing pressure to greatly increase
• pressure in left ventricle > aorta
• aortic valve opens
• ventricular ejection
• pressure is increasing then gradually decreases in ventricles
• pressure in aorta > left ventricle and so aortic valve closes
• isovolumetric relaxation - closed chamber
• pressure drops
• pressure in left atrium > left ventricle so mitral valve opens
• left ventricle starts to fill - pressure increases

Question 10

how is stroke volume calculated from EDV and ESV

Answer 10

SV = EDV - ESV
approx = 80ml

Question 11

How is ejection fraction calculated?

Answer 11

SV / EDV

Question 12

What are normal heart sounds

Answer 12

S1 and S2

Question 13

whats happening during S1 and S2

Answer 13

S1 - lubb
- closure of the tricuspid and mitral valves at the beginning ventricular systole
- aka the end of ventricular filling and atrial systole - beginning of isovolumetric contraction and ejection
S2 - dupp
- closure of the aortic and pulmonary valves at the beginning of ventricular diastole
- between lubb dupp is when you are getting ejection

Question 14

What are abnormal heart sounds

Answer 14

S3 - occasional
- turbulent blood flow into ventricles detected near end of first 1/3 diastole
- common in young
- not necessarily pathological
S4 - pathological in adults
- forceful atrial contraction against a stiff ventricle -potentially abnormal

Question 15

What does the area inside a left ventricle pressure-volume loop show

Answer 15

amount of stroke work done
relates to the amount of energy consumption used to produce stroke volume
important to consider in particular disease situations

Question 16

What is valve stenosis?

Answer 16

narrowing of valve, doesn’t fully open, reduces blood flow through it

Question 17

What does pressure-volume loop of aortic stenosis show?

Answer 17

• aortic valve not fully open
• build of high pressure in left ventricle
• poor ejection
• graph shows we’re only producing 50% SV, but using same energy

Question 18

What does pressure-volume loop of mitral stenosis show?

Answer 18

• mitral valve not fully open
• poor filling of left ventricle
• low EDV → less pressure
• reduced ejection
• poor SV ⇒ affects exercise

Question 19

Describe right atrium pressure changes

Answer 19

• blood returns to the right side of the heart pressure is going to increase.
• atrial contraction also increases pressure of RA
• this leads to ejection of blood from RA to RV ( A wave)
• whats left in the RA is very little blood, so pressure greatly decreases.
• at this point, ventricles are full and start ejecting blood to the pulmonary circulation (x descent)
• during this period of time, blood returns from systemic circulation back to the great veins and RA and so RA pressure starts to rise as it fills up (v wave)
• then, pressure rises in RA to the point where the tricuspid valve opens which causes the beginning of ventricular filling (y descent)
• rise in pressure in atria → decrease in pressure → increase in pressure

Question 20

what is the clinical relevance of right atria and jugular venous pressure changes

Answer 20

if RA is not working properly (not ejecting blood so well) → RV pressure builds up which then causes pressure in RA and great veins to increase aswell (knock on effect) → greater back pressure → elevated JVP

right sided heart failure