2: Force generation by the heart

Question 1

Cardiac muscle has a streaky appearance - what are these streaks called?

Answer 1

Striations

So cardiac muscle is described as ‘striated’

Question 2

Why is cardiac muscle striated?

Answer 2

Alternating actin and myosin proteins

(Actin has a lighter colour and myosin has a darker colour)

Question 3

Do muscles have a nerve supply?

Why?

Answer 3

No

Autorhythmicity - heart can generate its own nerve impulses

Question 4

What allows for cell-to-cell conduction of impulses between cardiac myocytes?

Answer 4

Gap junctions

Question 5

What property of gap junctions allows for electrical communication between cardiac myocytes?

Answer 5

Low resistance

Question 6

What is the All-or-none Law of the Heart?

Answer 6

All cardiac myocytes will respond to an action potential, no matter its strength

Question 7

The low resistance of gap junctions ensures that excitation reaches ___ cardiac myocytes.

Answer 7

all

Question 8

What is the function of desmosomes?

Answer 8

Provide mechanical adhesion - sticks cardiac myocytes together so they all tense up together

Question 9

Within a muscle fibre, fascicles contain ___ which are made up of sarcomeres.

Answer 9

myofibrils

Question 10

Myofibrils have alternating __ and __ protein segments.

Answer 10

thick , thin

Question 11

What is the smallest unit of contractile muscle?

Answer 11

Sarcomere

Question 12

What are the thin, lighter segments of myofibril made of?

Answer 12

Actin

Question 13

What are the thicker, darker sections of myofibril called?

Answer 13

Myosin

Question 14

What are the smaller functional units found within myofibrils called?

Answer 14

Sarcomeres

Question 15

Actin filaments ___ along myosin filaments to cause muscle ___.

Answer 15

slide along

muscle contraction

Question 16

The interactions between actin and myosin are dependent on what two molecules?

Answer 16

ATP

Ca²⁺

Question 17

ATP binds to myosin to trigger what?

Answer 17

Detachment of myosin cross bridge from actin

Cross bridge then slides along actin and rebinds

Question 18

Ca²⁺ triggers (binding / detachment) of myosin-actin.

Answer 18

Binding

Question 19

What ion is required to switch on myosin cross-bridge formation?

Answer 19

Ca²⁺

So ATP binds to myosin to detach it from actin, it then slides forward and if calcium is present, it rebinds (and the muscle has contracted)

Question 20

Name the two regulatory proteins found on actin filaments.

Answer 20

Tropomyosin

Troponin

Question 21

What is the name of the rope-like protein structure found on actin filaments?

Answer 21

Tropomyosin

Question 22

What protein blocks myosin binding sites on actin filaments until it is disabled by calcium ions?

Answer 22

Troponin

Question 23

Calcium binds to troponin causing a _____ change, moving the protein away and exposing the ___ binding sites on the ___ filaments.

Answer 23

conformational change

myosin-binding sites on actin filaments

Question 24

Ca²⁺ is released from the ____ ____ depending on the extracellular presence of Ca²⁺.

Answer 24

sarcoplasmic reticulum

Question 25

What triggers the release of Ca²⁺ ions from the sarcoplasmic reticulum of myofibrils?

Answer 25

Extracellular calcium - i.e Calcium-dependent Calcium release

Question 26

During systole…

1. Contractile machinery activated
2. Ca²⁺ influx during plateau phase of action potential
3. Ca²⁺ released from the sarcoplasmic reticulum
4. Ca²⁺ binds to troponin and allows myosin-actin cross-bridge binding

Arrange these statements in the correct order.

Answer 26

2 → 3 → 4 → 1

Question 27

What is the refractory period?

Answer 27

The period following an action potential in which it is not possible to produce another action potential

Question 28

During the plateau phase, how do Na⁺ channels ensure that another action potential (i.e depolarisation) does not take place?

Answer 28

They close

Question 29

In the descending phase, how do K⁺ channels ensure that another depolarisation does not take place?

Answer 29

They open

bringing membrane back down to K levels

Question 30

Why is the refractory period of the heart important?

Answer 30

It prevents generation of tetanic contractions of cardiac muscle (i.e constant heartbeats)

Question 31

What are tetanic contractions of the heart?

Answer 31

Sustained muscle contraction when the rate of action potentials in cardiac muscle is too high

Question 32

Contraction of ventricular muscle ejects the ___ volume.

Answer 32

stroke

Question 33

What is the definition of stroke volume?

Answer 33

The volume of blood ejected by each ventricle per heart beat

Question 34

What is the equation for stroke volume?

Answer 34

Stroke volume (SV) = End diastolic volume (EDV) - End systolic volume (ESV)

SV = EDV - ESV

Question 35

Which two types of mechanism regulate the stroke volume of the heart?

Answer 35

Intrinsic and extrinsic mechanisms

Question 36

What is intrinsic control of stroke volume?

Answer 36

Controls found within the heart muscle itself

Question 37

What is extrinsic control of stroke volume?

Answer 37

Control by the nervous system and hormones

Question 38

Intrinsic changes in stroke volume are brought about by…

Answer 38

end diastolic length of myocardial fibres (preload)

Question 39

Which volume determines the preload of myocardial fibres?

Answer 39

End Diastolic Volume (EDV)

Question 40

What is the cardiac preload?

Answer 40

The stretching of myocardial fibres at the end of diastole (which determines the stroke volume of the next heart beat)

Question 41

What determines the end diastolic volume?

Answer 41

Venous return

Question 42

1. End diastolic volume

determines

2. Diastolic length of myocardial fibres

determines

3. Venous return

determines

4. Cardiac preload

Arrange the numbers 1-4 in the correct order.

Answer 42

3 → 1 → 2 → 4

Question 43

What is Starling’s Law of the Heart?

Answer 43

The more the ventricle fills with blood during diastole (greater end diastolic volume) the greater the volume of ejected blood will be (greater stroke volume) during the resulting systolic contraction

i.e greater EDV = greater stroke volume

Question 44

Which law does this graph show?

Answer 44

Starling’s Law of the Heart

(increased EDV = increased stroke volume)

Question 45

Increased stretch has an effect on a regulatory protein found on actin.

What is this effect?

Answer 45

Increased stretch > increased affinity of troponin for Ca²⁺

Question 46

According to Starling’s Law of the Heart, optimum length in cardiac muscle is achieved by _____ the muscle.

Answer 46

stretching

Question 47

1. Increased stroke volume into the pulmonary artery by Starling’s Law
2. Increased venous return to left atrium from pulmonary vein
3. Increased venous return to right atrium
4. EDV of left ventricle increases
5. EDV of right ventricle increases

…causing increased stroke volume into the aorta by Starling’s Law.

Arrange 1-5 in the correct order.

Answer 47

3 → 5 → 1 → 2 → 4

Question 48

What is afterload?

Answer 48

The resistance into which the heart is pumping, imposed after the heart has contracted

Determined by TPR

Question 49

What happens if afterload increases?

Answer 49

1. The heart is unable is eject its full stroke volume, so some is left over

2. Thus EDV of the ventricles increases

3. So force of contraction increases by Starling’s Law

4. If chronic, ventricular hypertrophy may occur to overcome the resistance

Question 50

Which autonomic nervous division supplies ventricular muscle?

Answer 50

Sympathetic

(remember that parasympathetic impulses have no effect on contractility)

Question 51

Which post-synaptic neurotransmitter acts on ventricular muscle?

Answer 51

Noradrenaline (sympathetic division supplies heart muscle)

Question 52

Stimulation of sympathetic nerves (increases / decreases) force of contraction.

Answer 52

increases

Question 53

Sympathetic stimulation increases the force of contraction of ventricular muscle. What name can be given to this effect?

Answer 53

Positive inotropic effect

Question 54

Stimulation of the sympathetic nerves in the heart produces two different effects, what are they called?

Answer 54

Positive chronotropic effect (increased heart rate)

Postivie inotropic effect (increased force of contraction)

Remember sympathetic stimulation also reduces AV nodal delay

Question 55

Why does sympathetic stimulation increase the force of contraction of ventricular muscle?

Answer 55

Activation of Ca²⁺ channels causes greater Ca²⁺ influx

Question 56

What molecule mediates the activation of calcium channels associated with sympathetic stimulation of the heart?

Answer 56

cAMP

Question 57

The activation of calcium channels associated with sympathetic stimulation of the heart also reduces the durations of ___ and ___.

Answer 57

systole and diastole

(Thus increasing heart rate)

Question 58

What effect does sympathetic stimulation have on the Frank-Starling curve and why?

Answer 58

Shifts curve to the left

Contractility of the heart at a given EDV increases

Question 59

Explain the trends seen on this Frank-Starling curve.

Answer 59

Positive inotropic effect is an increase in the force of contraction so stroke volume increases

and the opposite

Question 60

Heart failure causes a shift to the ___ on a Frank-Starling curve.

Answer 60

right

Question 61

What effect does parasympathetic stimulation have on the force of contraction?

Answer 61

No effect

Parasympathetic stimulation influences rate, not force, of contraction

Question 62

Where in the body are adrenaline and nonadrenaline released?

Answer 62

Adrenal medulla

Question 63

What is cardiac output?

Answer 63

The volume of blood pumped by each ventricle per minute

Question 64

Write an equation for cardiac output.

Answer 64

Cardiac output = Stroke volume x Heart rate

CO = SV x HR

Question 65

What is the resting cardiac output in a healthy adult?

Answer 65

Approx. 5L

70ml SV x 70bpm = 4900ml CO