1.3.3 Action Potential Generation

Question 1

When both gates are open what will happen to g_Na and I_Na?

Answer 1

When both gates open g_Na and I_Na will both be increased.

Question 2

When threshold is achieved what happens?

Answer 2

At threshold there is a net depolarizing current due to active sodium channels. This will move V more positive - thus opening more Na activation gates (increasing gNa)

Question 3

What conformation are the voltage-gated sodium channels in when at normal resting potential (resting Na+ channel)?

Answer 3

At resting potential the inactivation gate is open and the activation gate is closed

Question 4

Answer 4

C

Question 5

What are symptoms of hypercalcemia?

Answer 5

Muscle weakness, tiredness, confusion, etc

Question 6

As membrane potential becomes more positive, what happens to the potassium delayed rectifier channels?

Answer 6

As it becomes more positive, activation gates slowly open on the potassium delayed rectifier channels.

Question 7

Depolarization of Na-gates acts as what kind of feedback loop?

Answer 7

Positive feedback loop

Question 8

At the peak of the action potential, what will cause repolarization (V moving away from E_Na)?

Answer 8

Even though all activation gates are opened, Na⁺ inactivation gates are closed. This will cause a decrease in g_Na and thus depolarization.

Question 9

Is the threshold value fixed within a cell?

Answer 9

NO - it depends of the balance between depolarizing and repolarizing currents

Question 10

What is important to not about the kinetics of the activation and inactivation gates? Why might this be important?

Answer 10

The inactivation gate opens and closes slowly and the activation gate opens and closes rapidly. Because of this, if a cell depolarizes quickly enough activation gates can open before inactivation gates have closed completely.

Question 11

What is conduction velocity?

Answer 11

Conduction velocity is how quickly an action potential propogates along a tissue. It is dependent on the magnitude of the depolarzing current during the upstroke of the action potential.

Question 12

Summarize the process of a nerve action potential.

Answer 12

At the resting potential, both Na- and K-voltage gated channels are closed. The status of the Na-channel is in the resting state. The K-channel is also in the resting state. During the upstroke of the action potential, sodium channels move from the closed (resting) state to the open (active) state. At the peak of the action potential, most of the sodium channels are in the open (active) state. The membrane depolarization that occurs during the upstroke phase also cause K-channels to transition from the closed (resting) state to an open (active) state. With time, the membrane depolarization that activated the Na-channels also causes the open (active) state to transition to a closed (inactivated) state. The repolarization phase results from opening of K-channels. During the undershoot, the open voltage-gated K-channels cause K-permeability to be greater than the potassium permeability that occurs at the resting potential and this causes membrane potential to approach the potassium Nernst potential. With time, the open (active) K-channels transition to the closed (resting) state. This causes K-permeability to decrease and membrane potential moves back to the resting potential.

Question 13

The magnitude of the depolarizing current during the upstroke of the action potential will determine?

Answer 13

Question 14

What are the two gates associated with the Voltage-Gated Sodium Channel?

Answer 14

Activation and Inactivation gate

Question 15

What is the relative refractory period?

Answer 15

During the time that inactive channels are being converted to resting channels, the cell can generate AP if a stronger depolarizing stimulus is given than normally required

Question 16

Answer 16

D

Question 17

The number of resting Na+ channels is dependent on what?

Answer 17

Having sufficient time during repolarization before the next depolarization stimulus occurs, and repolarizing to a sufficient extent.

Question 18

If resting potential is moved more positive, how will this affect membrane excitability?

Answer 18

Question 19

As membrane potential becomes more positive what will happen to Na-channels?

Answer 19

There will be an increased probability that their activation gates will be open

Question 20

Increasing fg_Na will do what to membrane potential? What formula is associated with that?

Answer 20

Increased fg_Na will move membrane potential towards the sodium Nernst potential. The image is the associated formula

Question 21

If the magnitude of the Na+ current during depolarization is decreased what will occur?

Answer 21

1. Threshold potential is more positive (decreased excitability)
2. Amplitude of AP is decreased
3. Rate of Rise of AP is decreased
4. Conduction velocity is decreased

Question 22

Answer 22

E

Question 23

What is the absolute refractory period?

Answer 23

The period where the cell cannot generate an AP regardless of the strength of the depolarizing stimulus (during the upstroke of the AP)

Question 24

What is the effect of hypercalcemia on the sodium activation curve?

Answer 24

Hypercalcemia will reduce excitability by shifting sodium activation curve more positive

Question 25

Answer 25

D

Question 26

What is the threshold point determined by?

Answer 26

If enough active Na⁺ channels are produced to reach a point where I_Na (depolarizing current) just barely exceeds I_K (repolarizing current), the cell has reached threshold

Question 27

When g_Na is increased what will this do to V?

Answer 27

V, the membrane potential, will be moved closer to E_Na

Question 28

What is the normal resting potential?

Answer 28

-70 to -80 mV

Question 29

What will be the result of decreased number of resting Na+ channels?

Answer 29

This will diminish the cell’s ability to generate I_Na . This is the underlying problem with hypo and hyperkalemia

Question 30

Answer 30

A

Question 31

Answer 31

C

Question 32

As the cell repolarizes what will occur to the sodium activation gates?

Answer 32

The activation gates will close first, then the inactivation gates will open again.

Question 33

Depolarization of an action potential is caused by what?

Answer 33

Increasing g_Na

Question 34

As the membrane potential moves more positive what happens to the inactivation gates?

Answer 34

They begin to slowly close