S3_L1: Cardiac Electrophysiology

Question 1

TRUE OR FALSE: The striations of cardiac muscles are similar to that of skeletal muscles

Answer 1

True

Question 2

How many phases does the fast response have?

Answer 2

5

Question 3

What is the effect of tetrodotoxin to the fast response?

Answer 3

Phase 1 disappears

Question 4

TRUE OR FALSE: The effective refractory period is from start of phase 0 to 1/3 of repolarization.

Answer 4

True

Question 5

TRUE OR FALSE: If a pacemaker’s frequency of discharge is faster, it can be a true pacemaker

Answer 5

True

Question 6

TRUE OR FALSE: The heart’s conducting system never allows
retrograde transmission of impulses

Answer 6

True

Question 7

TRUE OR FALSE: Faster HR greatly decrease diastolic filling time

Answer 7

True

Question 8

What is the effect of catecholamines to the heart?

Answer 8

(+) chronotropic and inotropic effect

Question 9

This impinges in the working cardiac muscles.

Answer 9

Purkinje fibers

Question 10

What is the effect of ACh to HR?
A. Tachycardia
B. Bradycardia

Answer 10

B. Bradycardia

Question 11

If the threshold potential is made less negative, what happens to the heart rate?
A. Tachycardia
B. Bradycardia

Answer 11

B. Bradycardia

If the slope of a pacemaker/prepotential is decreased, the threshold potential will be less steep and it will be reached after a
longer time, therefore the overshoot will also be at a later time causing the heart rate to be decreased.

Question 12

What happens if the phase 4 slope of the pacemaker potential is made steep?
A. Tachycardia
B. Bradycardia

Answer 12

A. Tachycardia

Question 13

If the SA Node is blocked, what will be the pacemaker?

Answer 13

AV node

Question 14

The normal or true pacemaker that is at the junction of the right atrium and superior vena cava. It is a remnant of the sinus venosus.

Answer 14

SA Node

Question 15

TRUE OR FALSE: Cardiac muscle cells branch and interdigitate

Answer 15

True

Question 16

Where are the T Systems of Cardiac muscles located?

Answer 16

At the z lines

Question 17

This exhibits the slow response action potential.

Answer 17

AV node

Question 18

TRUE OR FALSE: The slow response has an absent plateau

Answer 18

True

Question 19

In the fast response, what explains phase 0?
A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels
B. Opening of Ca++ channels
C. Na+ influx
D. Closure of Na+ and opening of K+ channels
E. K+ efflux

Answer 19

C. Na+ influx

Question 20

In the fast response, what explains phase 4?
A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels
B. Opening of Ca++ channels
C. Na+ influx
D. Closure of Na+ and opening of K+ channels
E. K+ efflux

Answer 20

A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels

Question 21

In the fast response, what explains phase 3?
A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels
B. Opening of Ca++ channels
C. Na+ influx
D. Closure of Na+ and opening of K+ channels
E. K+ efflux

Answer 21

E. K+ efflux

Question 22

In the fast response, what explains phase 2?
A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels
B. Opening of Ca++ channels
C. Na+ influx
D. Closure of Na+ and opening of K+ channels
E. K+ efflux

Answer 22

B. Opening of Ca++ channels

Question 23

In the fast response, what explains phase 1?
A. Return back to RMP, Na+ K+ ATPASE pump ions back, closure of K+ channels
B. Opening of Ca++ channels
C. Na+ influx
D. Closure of Na+ and opening of K+ channels
E. K+ efflux

Answer 23

D. Closure of Na+ and opening of K+ channels

Question 24

Muscles that exhibits the fast response action potential.

Answer 24

Ventricular muscles

Question 25

In the slow response, what completes the prepotential?

Answer 25

Ca++ via transient Ca++ channels

Question 26

In the slow response, what initiates the prepotential?

Answer 26

Opening of H channel; caused by funny current

Question 27

Determine the corresponding descriptions of the refractory period in cardiac excitability

1. Vulnerable period of the heart
2. May or may not be able to stimulate the heart
3. Cannot stimulate the heart regardless of mV
4. Going back to RMP
5. Electric shock must not be given at this period or else, V-tach (ventricular tachycardia) or V-fib (ventricular fibrillation) or asystole (flatline) could occur
6. Onset of depolarization to 1/3 of phase 3
   (repolarization)

A. Absolute (Effective) Refractory Period
B. Relative Refractory Period
C. Supranormal Period
D. Full Time Recovery

Answer 27

1. C
2. B
3. A
4. D
5. C
6. A

Question 28

Enumerate the 3 factors that determine pacemaker discharge frequency

Answer 28

1. Rate or slope of depolarization during phase 4
2. Level of threshold potential which must be attained
3. Magnitude of resting potential

Question 29

A low stroke volume results to a low (1)___ and high (2)___

Answer 29

1. Cardiac output
2. Heart rate

Question 30

The resting phase of the heart where ventricular filling happens. The time of this phase decreases when the heart beats faster

Answer 30

Diastole

Question 31

Bundle branches that divide into left anterior and left posterior fascicles. These fascicles will end up as the Purkinje system

Answer 31

Left bundle branches

Question 32

Arrange the following in the correct order of the conducting system of the heart

Choices: AV Node, Internodal pathways toward the atria, posterior internodal pathway of Thorel, Purkinje fibers, Bundle of His, middle internodal pathway of Wenckebach, Bundle branches, SA Node, anterior internodal pathway of Bachmann

Answer 32

1. SA Node
2. Internodal pathways toward the atria
3. anterior internodal pathway of Bachmann
4. middle internodal pathway of Wenckebach
5. posterior internodal pathway of Thorel
6. AV Node
7. Bundle of His
8. Bundle branches
9. Purkinje fibers

Question 33

Determine the corresponding descriptions of the components in the electrocardiogram (ECG)

1. ventricular repolarization which is in line
   with phase 3 of fast response
2. ventricular filling; found in diastole
3. atrial depolarization which is in line with
   atrial muscle depolarization
4. ventricular depolarization which is in line
   with fast response AP in ventricles

A. P wave
B. QRS
C. T wave
D. U wave

Answer 33

1. C
2. D
3. A
4. B

Question 34

Enumerate the 4 factors that affect pacemaker activity

Answer 34

1. Acetylcholine and vagal influence
2. Sympathetic activity
3. Temperature
4. Ions

Question 35

The Anterior Tract of Bachmann goes to the ___.

Answer 35

Left atrium

Question 36

Determine the corresponding descriptions of the components of the conduction system of the heart

1. conduction velocity is fastest & has the largest action potential
2. automatic cell with the greatest auto-rhythmicity
3. additional and separate fibers that bypass
   the bundle of His & connect atria &
   ventricles
4. beneath the endocardium on the (R) side of the atrial septum
5. penetrates the heart skeleton (trigone) & enters the ventricular septum

A. Sinoatrial node
B. Atrioventricular node
C. Bundle of His
D. Purkinje fibers
E. Posterior tract of Thorel
F. Bundle of Kent

Answer 36

1. D
2. A
3. F
4. B
5. C

Question 37

Determine the corresponding descriptions of the components of the conduction system of the heart

1. its transmission is always anterograde
2. converges to the AV Node
3. arise from bundle branches
4. single bundle of specialized tract
5. may not be sufficient to excite the next zone causing a first degree heart block

A. Sinoatrial node
B. Atrioventricular node
C. Bundle of His
D. Purkinje fibers
E. Posterior tract of Thorel
F. Bundle of Kent

Answer 37

1. B
2. E
3. D
4. C
5. B

Question 38

With regards to the layers of the heart, depolarization and repolarization occur from?

Answer 38

Depolarization: from endocardium to epicardium
Repolarization: from epicardium to endocardium

Question 39

Determine the corresponding descriptions of the types of cardiac action potential

1. Utilizes 1 ATP for one power stroke and 3 ATP for the restoration
2. RMP is -50 to -65 mV
3. Exhibited by fiber tracts & purkinje fibers
4. Slower rise of the upstroke (phase 0)
5. a Na+/Ca++ exchanger and Ca++ pump are used to restore ionic concentrations

A. Slow Response Action Potential
B. Fast Response Action Potential

Answer 39

1. B
2. A
3. B
4. A
5. B

Question 40

Determine the corresponding descriptions of the phases of the fast response action potential

1. Overwhelmed by the opening of calcium channel, calcium influx counteracted the repolarization caused by the efflux of potassium
2. Potassium channels remain
   open and will start to close
3. Once firing level is reached,
   voltage gated sodium channels open and sodium rushes into the cardiac muscle which causes spike potential
4. Sodium channels will close the inactivation gate to prevent equilibrium
   potential and it is the time to open potassium channels
5. Goes back to RMP and the sodium potassium pump will cause this

A. Phase 0
B. Phase 1
C. Phase 2
D. Phase 3
E. Phase 4

Answer 40

1. C
2. D
3. A
4. B
5. E

Question 41

TRUE OR FALSE: Action potential will always precede muscle twitch

Answer 41

True

Question 42

A muscle paralyzer acquired from blowfishes that can remove the notch (Phase 1 - peak and initial repolarization)
in the graph, making a fast response AP look like a slow one.

Answer 42

Tetrodotoxin

Question 43

RMP of cardiac cells in Fast response action potential

Answer 43

-90 mV

Question 44

Also known as pacemaker potential. It is caused by opening of transient calcium channels (that are abundant outside). The channels open and diffusion of calcium ensues, resulting in a graph that goes toward the positive side. This occurs during a slow response action potential.

Answer 44

Prepotential

Question 45

During a slow response action potential, long duration calcium channels will close once it is nearing the peak of the graph. This is because of what principle?

Answer 45

Principle of Equilibrium Potential

Equilibrium: Same amount of molecules inside and outside. When calcium is nearing its equilibrium potential, the gates of the channel will start to close because when equilibrium occurs, the cell dies