Electrical Activity of the Heart Flashcards Preview

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Flashcards in Electrical Activity of the Heart Deck (90)
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1
Q

What is contraction of heart muscle stimulated by?

A

Excitation contracting coupling

2
Q

What is A?

A

T-tubule

3
Q

What is B?

A

Actin

4
Q

What is C?

A

Myosin

5
Q

What is D?

A

Z-line

6
Q

What is the process of a normal muscle contraction?

A

1) Action potential reaches cell and causes Na voltage channels to open
2) Cell depolarises and causes calcium to be released from sarcoplasmic reticulum
3) Calcium binds to troponin and starts the muscle contraction

7
Q

Where is actin anchored?

A

Z line

8
Q

What are the deep invaginations in the muscle membrane known as?

A

T-tubules

9
Q

What are T-tubules?

A

Deep invaginations in the muscle membrane that interact with the organelles in the cell, such as the sarcoplasmic reticulum

10
Q

What allows cardiac cells to act as one big cell?

A

Gap junctions allowing the cells to communicate to each other by using signalling molecules

Desmosomes preventing the cells from separating during contraction

11
Q

What do gap junctions allow?

A

Cardiac cells to communicate with each other using signalling molecules

12
Q

What do desmosome junctions do?

A

Prevent cells from separating during a contraction

13
Q

What are intercalated disks?

A

Connect cardiac cells to allow them to work as a single functional organ

14
Q

What are the differences between the action potentials of skeletal muscle and cardiac muscle?

A

Action potential lasts for way longer in cardiac muscle

15
Q

How long does the action potential last for in skeletal muscle and cardiac muscle?

A

2ms in skeletal muscle

250ms in cardiac muscle

16
Q

What does the action potential lasting for ages in a cardiac cell allow?

A

Calcium to enter from outside the cell as well as sodium, allowing regulation of contraction

17
Q

What does the longer action potential allowing calcium and sodium to enter from outside the cell allow?

A

Heart contraction to be stronger or weaker

Refractory period is longer

18
Q

Which is cardiac and skeletal muscle has the longer refractory period?

A

Cardiac muscle

19
Q

What differences are there between cardiac and skeletal muscle due to cardiac muscle having a longer refractory period?

A

Skeletal muscle contractions can add together and accumulate (tetanus) due to many action potentials being added to one another

Cardiac muscle has to fully contract before it can be stimulated again and so they do not add onto each other

20
Q

Why is it important that the long refractory period of cardiac muscle mean tetanus cannot occur?

A

Heart needs to fully contract and then relax to pump blood

21
Q

What is tetanus?

A

Sustained muscle contraction evoked when the motor nerve that innervates a skeletal muscle emits action potentials at a high rate

22
Q

What is a sustained muscle contraction evoked when the motor nerve that innervates a skeletal muscle emits action potentials at a very high rate called?

A

Tetanus

23
Q

What do cardiac cells that have unstable resting membrane potentials act as?

A

Pacemakers

24
Q

What does having pacemakers allow a cell to do?

A

Depolarise again quicker

25
Q

Is there a greater K+ concentration inside or outside the cell?

A

Inside

26
Q

Is there a greater Na+ concentration inside or outside the cell?

A

Outside

27
Q

Is there a greater Ca2+ concentration inside or outside the cell?

A

Outside

28
Q

What causes the resting membrane potential of a cell?

A

At rest K+ gated channels are open (leaky) which makes the cell more negative until equilbrium is rached at -90mV

29
Q

What is the resting membrane potential (RMP) of cardiac muscle?

A

-90mV

30
Q

What is the process of non-pacemaker action potential?

A

1) Resting membrane potential (high resting permeability to K+
2) Initial depolarisation (increase in permeability to Na+)
3) Plateau (increase in permeability to Ca2+, L-type, and decrease in permeability to K+)
4) Repolarisation (decrease in permeability to Ca2+ and increase in permeability to K+)

31
Q

What causes the resting membrane potential in non-pacemaker cells?

A

High resting permeability to K+

32
Q

What causes the initial depolarisation in non-pacemaker cells?

A

Increase in permeability to Na+

33
Q

What causes the plateau in non-pacemaker action potentials?

A

Increase in permeability to Ca2+ (L-type)

Decrease in permeability to K+

34
Q

What causes the repolarisation of non-pacemaker action potential?

A

Decrease in permeability to Ca2+

Increase the permeability to K+

35
Q

What are the 2 different kinds of calcium channels?

A

L-type

T-type

36
Q

Do L-type or T-type calcium channels let lots of calcium in?

A

L type

37
Q

What cause the pacemaker potential (pre-potential) in a pacemaker action potential?

A

Gradual decrease in permeability to K+

Early increase in permeability to Na+

Late increase in permeability to Ca2+ (T-type)

38
Q

What causes the action potential in the pacemaker action potential?

A

Increase in permeability to Ca2+ (L-type)

39
Q
A
40
Q

What does the pacemaker action potential of the heart explain?

A

Autorhythmicity

41
Q

What brings heart cells to action potential in the first place?

A

Pacemaker action potential

42
Q

How would you describe the difference between pacemaker and non-pacemaker cells?

A

Not black and white, it is a spectrum

43
Q

What is the pacemaker cell of the heart?

A

The one with the fastest rhythm, all cells around it take up this rhythm

44
Q

What can electrical activity be modulated by?

A

Sympathetic and parasympathetic systems

Drugs

Temperature

Hyperkalemia

Hypokalemia

Fibrillation and heart block

Hypercalcemia

Hypocalcemia

45
Q

What are examples of drugs that alter the electrical activity?

A

Ca2+ channel blocker (decrease force of contraction)

Cardiac glycocides (increases force of contraction)

46
Q

What effect does Ca2+ channel blockers have on electrical activity?

A

Decreases force of contraction

47
Q

What effect does cardiac glycocides have on electrical activity?

A

Increases force of contraction

48
Q

What effect does temperature have on electrical activity?

A

Increases about 10bpm per 1oC

49
Q

What effect does hyperkalemia have on electrical activity?

A

Fibrillation and heart block

50
Q

What is hyperkalemia?

A

High plasma K+

51
Q

What is hypokalemia?

A

Low plasma K+

52
Q

What is high plasma K+ called?

A

Hyperkalemia

53
Q

What is low plasma K+ called?

A

Hypokalemia

54
Q

What effect does hypercalcemia have on electrical activity?

A

Increased heart rate and force of contraction

55
Q

What effect does hypocalcemia have on electrical activity?

A

Decreased heart rate and force of contraction

56
Q

What is hypercalcemia?

A

High plasma Ca2+

57
Q

What is high plasma Ca2+ called?

A

Hypercalcemia

58
Q

What is low plasma Ca2+ called?

A

Hypocalcemia

59
Q

What is hypocalcemia?

A

Low plasma Ca2+

60
Q

What is fibrillation?

A

Irregular heartbeat

61
Q

What is irregular heartbeat called?

A

Fibrillation

62
Q

What is heart block?

A

Blocking action potentials getting from the atrium to the ventricles

63
Q

What is blocking the action potentials getting from the atrium to the ventricles called?

A

Heat block

64
Q

What ensures that both atriums and both ventricles contract at the same time?

A

Special conducting system

65
Q

What does the special conducting system ensure?

A

Both atriums and ventricles contract at the same time

66
Q

What is A?

A

Superior vena cava

67
Q

What is B?

A

Sinoatrial node

68
Q

What is C?

A

Right atrium

69
Q

What is D?

A

Right bundle branch

70
Q

What is E?

A

Right ventricle

71
Q

What is F?

A

Purkinje fibres

72
Q

What is G?

A

Inferior vena cava

73
Q

What is H?

A

Left bundle branch

74
Q

What is I?

A

Left ventricle

75
Q

What is J?

A

Left atrium

76
Q

What is K?

A

Bundle of His

77
Q

What is L?

A

Atrioventricular node

78
Q

What is the process of the activation of the special conducting system?

A

1) Sinoatrial node (about 0.5m/s)
2) Antrioventricular node (about 0.05m/s, acts as a delay)
3) Bundle of His
4) Purkinje fibres (about 5ms, acts as a rapid conducting system)

79
Q

What do the left and right bundles of His break down into>

A

Purkinje fibres

80
Q

What do purkinje fibres ensure?

A

All of the ventricle contracts at the same time

81
Q

Why is the delay of the antrioventricular node required?

A

So the atrium can get as much blood as possible into the ventricles

82
Q

What is the wave seen on an electrocardiogram?

A

Summation of little action potentials in individual myocytes

83
Q

What is an electrocardiogram?

A

Test used to check hearts rhythm and electrical activity

84
Q

What is a test used to check hearts rhythm and electrical activity?

A

Electrocardiogram

85
Q

What is A?

A

P wave

86
Q

What is BCD complex?

A

QRS complex

87
Q

What is E?

A

T wave

88
Q

What does the P wave correspond to?

A

Atrial depolarisation

89
Q

What does the QRS complex correspond to?

A

Ventricular depolarisation

90
Q

What does the T wave correspond to?

A

Ventricular repolarisation

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