11.28 A

Question 1

Describe the pathway of electrical conductance through the heart.

Answer 1

• SA node through the atria to the AV node along the internodal pathways
• AV node to Bundle of His
• through the left and right bundle branches
• to the purkinje fibers
• through the ventricular muscle

Question 2

If the SA node is damaged, what takes over pacemaking in the heart?

Answer 2

usually the AV node

Question 3

How does conductance along the internodal pathways compare to conductance through the atria?

Answer 3

the conduction velocity in the internodal pathway is faster than in atrial muscle, so the AP will reach the AV node before the entire atrial wall has depolarized

Question 4

Describe the conduction velocity through the AV node.

Answer 4

it is much slower than in other areas of the heart

Question 5

Which action potentials in the heart are calcium dependent?

Answer 5

those in the SA and AV nodes

Question 6

Which action potentials in the heart are sodium dependent?

Answer 6

atrial and ventricular myocytes, purkinje fibers, and bundle of his

Question 7

The P wave of an EKG represents what electrical activity in the heart?

Answer 7

atrial depolarization

Question 8

The ST segment of an EKG represents what event?

Answer 8

phase 2 of ventricular action potentials

Question 9

How does the resting potential of SA node cells differ from that of cardiomyocytes?

Answer 9

it is more positive, closer to -50 mV, and it isn’t stable

Question 10

What molecules give SA it’s unstable resting potential?

Answer 10

funny sodium channels

Question 11

What is phase 0 of an SA node action potential?

Answer 11

the upstroke, dependent on calcium current

Question 12

What is phase 3 of an SA node action potential?

Answer 12

the repolarization phase where potassium current outweighs calcium current

Question 13

What is phase 4 of an SA node action potential?

Answer 13

the upstroke of the action potential due to calcium channels

Question 14

SA node depolarization is dependent on ___ current while SA node repolarization is dependent on ____ currents.

Answer 14

calcium; potassium

Question 15

What is MDP?

Answer 15

• maximum diastolic potential
• the most negative potential in the SA node
• equivalent to the resting potential of the SA node

Question 16

The slope of SA node phase 4 and the value of MDP are dependent on what?

Answer 16

the balance between the funny sodium current and hte potassium current

Question 17

What is the major difference between the action potential in the SA node and AV node?

Answer 17

• the slope of phase IV in the AV node isn’t as steep

- thus the intrinsic firing rate is slower

Question 18

The intrinsic firing rate is slower in which pacemaker node of the heart?

Answer 18

the AV node

Question 19

How is the funny sodium channel gated?

Answer 19

it has a single gate, the activation gate, which opens during repolarization

Question 20

When do the activation gates of funny sodium channels open during an SA or AV action potential?

Answer 20

during repolarization

Question 21

How are voltage-gated L-type calcium channels gated?

Answer 21

a slow opening and closing inactivation gate and a fast opening and closing activation gate

Question 22

What is the calcium window?

Answer 22

the overlap of the calcium inactivation gate opening and the activation gate closing or vice versa

Question 23

L-type calcium channels in the nodes are equivalent to ____ channels in the myocytes, except that…

Answer 23

voltage gated sodium channels except for the existence of the calcium window for the L-type channels

Question 24

Describe the phases of the ventricular action potential.

Answer 24

• phase 0: upstroke
• phase 2: stable plateau
• phase 3: repolarization
• phase 4: stable resting potential

Question 25

The phase 2 plateau of the ventricular action potential is due to a balance of what currents?

Answer 25

potassium and calcium

Question 26

What role do sodium channels play in the ventricular action potential?

Answer 26

they create a transient positive current during the upstroke just long enough to open calcium channels

Question 27

What role do calcium channels play in the ventricular action potential?

Answer 27

they sustain depolarization after they are opened by the sodium current and oppose the repolarizing potassium current

Question 28

There are many potassium currents that function in the ventricular action potential, but the most important is which?

Answer 28

the repolarizing current of phase 3 that is mediated by potassium rectifying channels

Question 29

Via what mechanism does the autonomic nervous system regulate heart rate?

Answer 29

G-protein coupled regulation of ionic currents via NE and ACh

Question 30

Sympathetic innervation of the SA node is mediated by what NT?

Answer 30

norepinephrine

Question 31

Parasympathetic innervation of the SA node is mediated by what NT?

Answer 31

acetylcholamine

Question 32

NE released in the SA node by sympathetic innervations acts on what receptor?

Answer 32

beta-1

Question 33

Increased sympathetic firing to the heart will increase heart rate primarily modulating what current?

Answer 33

increasing the funny sodium current in the SA node

Question 34

Sympathetic firing to the heart increases what currents?

Answer 34

funny sodium and calcium

Question 35

Parasympathetic firing to the heart decreases what currents?

Answer 35

funny sodium and calcium

Question 36

How does increased sympathetic firing increase the funny sodium current?

Answer 36

by shifting the activation curve for the channels in a less negative direction

Question 37

How do low and high frequency parasympathetic firing to the heart differ in their effects?

Answer 37

• low decreases funny sodium current so the phase 4 slope decreases
• high decreases the MAD so the cell has further to go to reach threshold

Question 38

Which autonomic innervation of the SA node is in greater control of heart rate under normal conditions?

Answer 38

parasympathetic inhibition

Question 39

What is the intrinsic rate of SA firing?

Answer 39

110 bpm but it is typically being inhibited and lowered by parasympathetic innervation

Question 40

What current dictates the width of the QRS complex?

Answer 40

the sodium current because it determines the rate of rise of phase 0 and conduction velocity of the action potential through the ventricles and atria

Question 41

A spiked T wave will result from an increase in what current?

Answer 41

potassium, since it largely dictates the rate of repolarization

Question 42

How does exercise affect the ventricular action potential?

Answer 42

• increased sympathetic nerve firing
• increased calcium and potassium currents (no change in sodium) in myocytes
• increased calcium makes phase II of AP more positive
• increased potassium makes phase III occur sooner

Question 43

How does NE promote the activation of voltage-dependent calcium channels?

Answer 43

• calcium channels must be phosphorylated to open
• NE acts on a G protein-coupled receptor (beta receptor)
• the G protein phosphorylates the calcium receptor

Question 44

How will conditions that reduce the level of ATP within myocytes affect the ventricular action potential?

Answer 44

• calcium channels won’t be phosphorylated
• the duration of the ventricular action potential will be reduced
• the QT interval will be reduced

Question 45

Sympathetic stimulation does what to the calcium window?

Answer 45

it increases it but shifting the activation gate curve towards more negative potentials

Question 46

Why can sympathetic-mediated calcium window increasing cause problems?

Answer 46

if the rate of repolarization is slowed, the inactivation gate may reopen before the activation gate has a chance to close

Question 47

Although increasing the calcium window via sympathetic stimulation has the potential to be problematic why isn’t it?

Answer 47

• the possible problem occurs if the rate of repolarization is slowed
• sympathetic firing will also increase sodium current, though so repolarization usually speeds up with sympathetic firing

Question 48

Describe how parasympathetic firing decreases cardiac currents.

Answer 48

• release of ACh, which binds to an M2-muscarinic receptor
• activation of an inhibitory G protein
• inhibition of a kinase
• less phosphorylation of ion channels

Question 49

Describe how sympathetic firing increases cardiac currents.

Answer 49

• release of NE, which binds a B1 receptor
• activation of a stimulatory G protein
• acativation of a kinase
• more phosphorylation of ion channels

Question 50

Sympathetic firing will ____ heart rate and ___ duration of the ventricular action potential.

Answer 50

increase; decrease

Question 51

How do changes in heart rate correlate to changes in duration of the ventricular action potential?

Answer 51

they don’t necessarily, the two are independent

Question 52

Which are more prominent, end-to-end gap connections or side-to-side connections?

Answer 52

end-to-end ones

Question 53

Is conduction velocity through myocytes faster in a manner parallel or perpendicular to fiber direction?

Answer 53

parallel

Question 54

What is anisotropic conduction?

Answer 54

the idea that conduction velocity through myocytes is greater in a direction parallel to fiber direction than perpendicular to it

Question 55

How might ischemia impair conduction of the action potentials through the heart?

Answer 55

• ischemia causes reduced metabolic activity
• this leads to increased intracellular sodium and other ions
• these increases will increase gap junction resistance

Question 56

What are some factors that increase gap junction resistance?

Answer 56

• increased intracellular sodium
• increased intracellular calcium
• intracellular acidosis
• decreased intracellular cAMP

Question 57

What is the functional refractory period?

Answer 57

the refractory period created by the combination of the absolute and relative refractory periods

Question 58

How are refractory periods in cardiomyocytes so important?

Answer 58

• because they prevent an action potential from continuously cycling and propagating through the muscle
• refractory periods prevent the initial wave of excitation from re-exciting the ventricle

Question 59

A decrease in conduction velocity will likely cause what problem in the heart?

Answer 59

it will negate the refractory period and allow the initial action potential to re-excite the ventricle