Cardiac Contraction

Question 1

What is the duration of an action potential?

Answer 1

200-500ms

Question 2

what is the amount of diastolic Ca2+?

Answer 2

100nM

Question 3

What is the amount of systolic Ca2+?

Answer 3

10 μM

Question 4

What is cell shortening like?

Answer 4

sub-maximal (not all or nothing)

Question 5

When does cell shortening happen?

Answer 5

During depolarization ‘plateau’ phase of action potential when ICa is generated

Question 6

When does cell relaxation happen?

Answer 6

During repolarisation of action potential

When Ca2+ signal is reduced

Question 7

How does electrical excitability contract cardiac myocytes?

Answer 7

• contraction is determined by an increase Ca2+
• Greater increases Ca2+ = increased force of contraction
• Intracellular Ca2+ levels increase from 0.1 μM to about 10 μM

Question 8

What are T tubules?

Answer 8

→ Extensions of the cell membrane (sarcolemma) that penetrate into the center of cardiac muscle cells

Question 9

What is the sarcoplasmic reticulum?

Answer 9

→ Membrane bound structure within muscle cells similar to the endoplasmic reticulum in other cells and stores Ca 2+

Question 10

What is a ryanodine receptor?

Answer 10

→ Intracellular Ca2+ channel

Question 11

What is the process of cardiac contraction?

Answer 11

→ Action potential depolarizes T tubules and activates VGCC causing a Ca2+ influx
→ Ca2+ binds to RyR located on the SR - close association with T tubules
→ Release of Ca2+ from the SR - CICR
→Ca2+ binds to troponin and there is displacement of tropomyosin / troponin complex which exposes the active sites on the actin
→Myosin thick filament heads bind to the active sites
→Myosin head ATPase activity releases energy (ATP to ADP) and the filaments slide

Question 12

What are the myosin-actin binding sites blocked by at rest?

Answer 12

→ Troponin-tropomyosin complex

Question 13

How does a rise in calcium cause the actin-myosin cross bridge to be formed?

Answer 13

→Ca2+ displaces troponin-tropomyosin so the actin-myosin binding sites are exposed and an actin-myosin cross bridge is formed

Question 14

What does a rise in Ca2+ cause?

Answer 14

→ More sites exposed
→ More cross-bridges
→ Greater contractility

Question 15

What is troponin composed of?

Answer 15

→ 3 regulatory sub units

Question 16

What is TnT?

Answer 16

→ Troponin T which binds to tropomyosin

Question 17

What is TnI?

Answer 17

→ Troponin I which binds to actin filaments

Question 18

What is TnC?

Answer 18

→ Troponin C binds Ca2+

Question 19

What does binding of Ca2+ to TnC lead to?

Answer 19

→ conformational changes of tropomyosin and the exposure of actin binding sites

Question 20

What are TnI and TnT markers for?

Answer 20

→ Plasma markers for cardiac cell death

→ following MI

Question 21

How does relaxation occur?

Answer 21

→ Action potential repolarization (K+ ions) repolarize T tubules
→ VGCC close and there is a decrease of Ca2+ influx
→ There is no Ca2+ influx so no CICR
→ Extrusion of Ca2+ from the cell (30%) by the Na+/Ca2+ exchanger
→ Ca2+ uptake into the SR via SR Ca2+ ATPase (SERCA 70%) Ca2+ in SR for next contraction
→ Uptake of Ca2+ in mitochondria
→ Reduction in Ca2+ myosin head ATPase activity releases energy (ATP to ADP)
→ Prevention of contraction mechanism

Question 22

What are drugs used for in relation to contractility?

Answer 22

→ used to increase contractility of the heart

→ correct acute chronic heart failure

Question 23

What do sympathetic mimetic drugs do?

Answer 23

→ Increase VGCC activity

Question 24

What do cardiac glycosides do and what are they used for ?

Answer 24

→ Reduce Ca2+ extrusion

→ used for chronic heart failure

Question 25

What are cardiac glycosides and sympathetic mimetic drugs an example of?

Answer 25

→ Positive INOTROPES

Question 26

What does noradrenaline do?

Answer 26

→ Acts on B1 adrenoceptors to increase contractility

Question 27

What are the 4 effects of sympathetic stimulation on the heart?

Answer 27

→Positive inotropic effect
→ Positive chronotropic effect
→ Positive dromotropic effect
→ Lusitropic effect

Question 28

What is a positive inotropic effect?

Answer 28

→ Increased contractility of the heart

Question 29

What is a positive chronotropic effect?

Answer 29

→ Increased heart rate

Question 30

What is a positive dromotropic effect?

Answer 30

→ Increased conduction through the AV node

Question 31

What is a lusitropic effect?

Answer 31

→ Increased rate of relaxation

→ K+ channels + SR Ca2+ ATPase

Question 32

How does digoxin work?

Answer 32

→ Inhibits Na+/K+ ATPase
→ Build up of Na+
→ Less Ca2+ extrusion by Na/Ca exchanger
→ More Ca2+ uptake into stores and greater CICR

Question 33

When are dobutamine and dopamine used?

Answer 33

→ B1 adrenoceptor stimulants

→ May be used in acute heart failure

Question 34

When is glucagon used?

Answer 34

→ Used in patients with acute heart failure who are taking B blockers
→ Stimulates Gs pathway increasing cAMP and PKA activity

Question 35

When is Amrinone used and how does it work ?

Answer 35

→ Phosphodiesterase inhibitor
→PDE3(heart specific) converts cAMP into AMP
Reduced PKA activity- limiting contractility
→ PDE inhibition leads build up of cAMP that activates PKA to phosphorylate VGCCs and  Ca2+ influx.

Only used in severe cases eg. those waiting for heart transplants.​

Question 36

What is a sarcomere?

Answer 36

cause muscle contraction when their component actin and myosin filaments move relative to each other. The varying actin myosin overlap is shown for systole (contraction) and diastole (relaxation).​

Question 37

Describe the graph of contraction

Answer 37

Depolarisation wave sweeps through the heart. As it reaches each cell it is enough to reach the threshold for Na+ channel opening.

1. Na+ channels open allowing Na+ to enter and depolarise the cell. ​
2. Voltage gated Ca2+ channels open​
3. Plateau phase Ca2+ influx & Ca2+ induced Ca2+ release (CICR). ​

Force of contraction proportional to intracellular calcium [Ca2+]i

4. Ca2+ channels close & K+ channel open fully allowing K+ to leave and repolarising the cell – muscle relaxation occurs.
5. Stable - Na+/K+ pump ​

3Na+ out & 2K+ in

Question 38

Recall the concentrations of calcium in the cell

Answer 38

Diastolic [Ca2+]I ̴ 0.1 μM ​

Normal systole [Ca2+]i may rise ̴ 1 μM​

Maximum systole [Ca2+]i may rise ̴10 μM​

Cell shortening usually less than maximum

Question 39

What are the results of increased protein kinase?

Answer 39

Increased Ca2+ channel so higher Ca2+ levels and greater contraction​

Increased K+ channel opening so faster repolarisation and shorter action potential…leads to faster heart rate​

Increased sarcoplasmic reticulum Ca2+ATPase, so uptake of Ca2+ into storage by SR allowing faster relaxation​

Overall stronger faster contractions but same diast