Mechanical properties of the heart 2

Question 1

What are the two main phases of the cardiac cycle?

Answer 1

diastole and systole

Question 2

What is end diastolic volume?

Answer 2

The volume of blood in the ventricle at the end of ventricular filling - around 130ml

Question 3

What does the end diastolic volume consist of?

Answer 3

End systolic volume
Amount added in atrial systole
Amount added into atrial diastole

Question 4

What is end systolic volume?

Answer 4

The volume left in the ventricle at the end of contraction - around 60ml

Question 5

What is stroke volume?

Answer 5

The volume of blood ejected by ventricular contraction - around 70ml

Question 6

How can stroke volume be calculated?

Answer 6

EDV-ESV

Question 7

What is ejection fraction and how can it be calculated?

Answer 7

The proportion of the end diastolic volume that is pumped out of the heart
SV/EDV

Question 8

What is normal ejection fraction and what happens to it in a person with heart failure?

Answer 8

normal - 65%

can drop to 35% in someone with heart failure

Question 9

What is a normal heart rate?

Answer 9

72 bpm

Question 10

What is normal cardiac output?

Answer 10

5.04L/min

Question 11

Describe what happens during atrial systole

- include the anatomy, pressure changes and any ECG/heart sound (abnormal)

Answer 11

Anatomy:
The blood is in the atria and it contracts

Pressure changes:
The atrial pressure shows a small increase (a wave), there may also be a jugular pulse to to atrial contraction pushing some blood back up the jugular vein

ECG:
P wave marks atrial systole

Heart sounds:
Abnormal s4 sound can be heard causes by valve incompetency. This could be due to pulmonary embolism, congestive heart failure or tricuspid incompetence

Question 12

Describe what happens during isovolumic contraction

- include the anatomy, pressure changes and any ECG/heart sound

Answer 12

Anatomy:
Contraction of ventricles with no change in volume, only pressure build up (both valves are closed). Muscles don’t change length

Pressure changes:
The AV valve shuts when ventricular pressure exceeds atrial. The ventricular pressure approaches that of aortic without exceeding it so aortic valve doesn’t open. Only when pressure exceeds afterload it opens.

ECG:
QRS complex marks ventricular depolarisation

Heart sounds:
S1 sound heard, the lub sound caused by AV valves closing

Question 13

Describe what happens during rapid ejection

- include the anatomy, pressure changes and any ECG/heart sound

Answer 13

Anatomy:
Aortic and Pulmonary valves open.

Pressure Changes
As ventricles isotonically contract, the ventricular pressure rapidly rises and exceeds aortic pressure (the afterload) and so the semilunar valves open and ventricular volume decreases.
The ‘c’ wave is caused by the pushing of the tricuspid valve into the atrium causing a small pressure increase in the jugular vein

ECG Changes & Heart Sounds:
None

Question 14

Describe what happens during reduced ejection

- include the anatomy, pressure changes and any ECG/heart sound

Answer 14

Anatomy:
Aortic and Pulmonary valves begin to close - end of systole, blood leaves ventricles slowly

Pressure Changes:
As blood has left the ventricles, ventricular volume and pressure begin to decrease. Semilunar valves begin to shut as pressure gradient causes backflow from the arteries.

ECG Changes:
T wave is due to ventricular re-polarisation

Heart sounds:
None

Question 15

Describe what happens during isovolumic relaxation

- include the anatomy, pressure changes and any ECG/heart sound

Answer 15

Anatomy:
Aortic and Pulmonary valves have shut.

Pressure Changes:
Atria have filled with blood but due to the AV valves being shut, the atrial pressure rises.
The ‘v’ wave is due to blood pushing the tricuspid valve (this gives the second jugular pulse).
DICHROTIC notch – A small, sharp increase in aortic pressure due to rebound pressure against the aortic valve as the distended aortic wall relaxes.

ECG Changes:
None

Heart Sounds:
The S2 sound is heard when the aortic and pulmonary valves shut - dub

Question 16

Describe what happens during rapid ventricular filling

- include the anatomy, pressure changes and any ECG/heart sound

Answer 16

Anatomy:
AV valves open, ventricles fill.

Pressure Changes:
Ventricular volume increases while atrial pressure falls.
This filling is passive and not isometric.

ECG Changes:
None

Heart Sounds:
An abnormal S3 may be heard which signifies turbulent ventricular filling.
Can be due to severe hypertension or mitral incompetence.

Question 17

Describe what happens during reduced ventricular filling

- include the anatomy, pressure changes and any ECG/heart sound

Answer 17

Anatomy
Also called ‘Diastasis’

Pressure Changes:
Ventricular volume increases more slowly.

ECG Changes & Heart Sounds:
None

Question 18

What are the 7 stages of the cardiac cycle?

Answer 18

• Atrial systole
• Isovolumic contraction
• Rapid ejection
• Reduced ejection (both ejections can be counted as one)
• Isovolumic relaxation
• Rapid ventricular filling
• Reduced ventricular filling

Question 19

Pressure Volume Loops

Answer 19

The graph is ventricular pressure vs ventricular volume.

1. The EDV – The ventricles are full but haven’t generated any isotonic pressure.
2. Isovolumic contraction – The volume hasn’t changed but the isotonic contraction generates a large increase in pressure.
3. The afterload pressure is reached (aortic pressure) and then ventricle begins to expel blood into the aorta (pressure rise and fall). This ends at the ESV. 2 to 3 = SV!
4. Pressure falls due to Isovolumic relaxation.

Question 20

Frank Starling Relationship In Vivo

Answer 20

 Instead of force, it is pressure and instead of length, it is volume. These are the in vivo correlates in the Frank-Starling relationship.
Point 3 – Represents the ESV so the active force curve tangent at this point represents the End-Systolic PV line.

Question 21

Ventricular volume vs ventricular pressure loop

Answer 21

• When afterload increases, more pressure is needed to open the aortic valve so point 2 on pressure volume loop (second highest point representing afterload) moves in y-direction
• Point 1 (third highest point is preload) remains the same as the EDV is the same

Question 22

How can the contractility of the heart be increased?

Answer 22

increased by sympathetic stimulation

Question 23

How can the stroke volume be changed?

Answer 23

change preload, afterload and contractility

Question 24

How is the pressure volume loop affected during exercise to increase SV and CO?

Answer 24

• Increase in contractility (active force) increases the stroke volume so point 3 moves further left.
• During exercise contractility is increased due to increased sympathetic activity.
• Changes in the peripheral circulation (e.g. vasoconstriction) cause more blood to return to heart so EDV (preload) increases – Point 1&2 move to the right.
• Increase in contractility moves points 3&4 to the left so an increase in SV occurs in total.

Question 25

Does the right side of the heart have lower pressures than the left?

Answer 25

Yes

Question 26

Is stroke volume the same on both sides of the heart?

Answer 26

yes

Question 27

What are blood pressure valves for systemic and pulmonary values?

Answer 27

Systemic - 120/80 mmHg

Pulmonary - 25/5 mmHg

Question 28

What is the pulmonary artery wedge pressure and what is high PAWP associated with?

Answer 28

• This measures pressures in the heart so by measuring in the pulmonary artery (right side), you can measure the preload on the left side of the heart (as the sides are linked by the pulmonary circuit).
• PAWP is elevated with problems in the left side of the heart.

Question 29

On average how long is systole and 1 cardiac cycle?

Answer 29

0. 3s

0. 8s

Question 30

What are the pressures in the RA, LA, RV, LV, aorta and pulmonary artery?

Answer 30

RA: 0 - 8 
LA: 8 - 10
RV: 25/5 
LV: 125/5
Pulmonary artery: 25/12 
Aorta: 120/80

Question 31

What is a measure of heart contractility?

Answer 31

Ejection fraction