Action potential mechanisms

Question 1

A potential difference exists across the membrane of all cells. What is this called?

Answer 1

The resting membrane potential

Question 2

In the resting membrane potential what is the ICF like in respect to ECF?

Answer 2

• ICF is negative with respect to the ECF

Question 3

There are equal numbers of +ve and -ve charges in the ECF and ICF. How come the ICF is negative with respect to the ECF?

Answer 3

• Because ion/charge distribution is ‘polarised’

Question 4

Are negative charges on the inside or outside of the plasma membrane of a cell?

Answer 4

• On the inside

Question 5

Are positive charges on the inside or outside of the plasma membrane of a cell?

Answer 5

Outside

Question 6

Is energy required to keep a cell at the resting membrane potential?

Answer 6

Yes

Question 7

Are there more Na+ ions in the ECF or the ICF?

Answer 7

The ECF

Question 8

Are there more K+ ions in the ECF or the ICF?

Answer 8

ICF

Question 9

Does sodium want to diffuse into or out of the cell?

Answer 9

Wants to diffuse into the cell

Question 10

Does potassium want to diffuse into or out of the ce ll?

Answer 10

Out of the cell

Question 11

When the cell is at resting potential is the membrane permeable to Na+ ions?

Answer 11

• No, it is impermeable

Question 12

When the cell is at resting potential is the membrane permeable to K+ ions?

Answer 12

It is permeable

Question 13

What does diffusion of K+ out of the cell leave an excess of inside the cell?

Answer 13

• Leaves an excess of -ve charge inside the cell

- This potential gradient arising from diffusion is the ‘membrane potential’

Question 14

How does a resting membrane potential arise?

Answer 14

From the separation of charges on either side of the membrane

Question 15

What happens to the small amount of sodium That manages to leak into the cell?

Answer 15

It is expelled by the Na+/K+ pump

Question 16

Although the RMP is due mainly to diffusion of K+ from cell interior the Na+/K+ pump also contributes. How does it do this? (2 points)

Answer 16

• Contributes by exchanging unequal numbers of Na+ and K+

- The pump moves 3 Na+ outwards and 2 K+ inwards

Question 17

How many Na+ ions does the Na+/K+ pump move outwards?

Answer 17

3 ions

Question 18

How many K+ ions does the Na+/K+ pump move inwards?

Answer 18

2 ions

Question 19

The Na+/K+ pump is ‘electrogenic’, what does this mean?

Answer 19

It produces a change in the electrical potential of a cell

Question 20

Is ATP required for the Na+/K+ pump to work?

Answer 20

Yes

Question 21

What is the rising phase of an action potential due to?

Answer 21

Due to a SODIUM INFLUX

Question 22

What is the falling phase of an action potential due to?

Answer 22

• Due to POTASSIUM EFLUX

Question 23

What are ion channels made from?

Answer 23

Membrane proteins (more specifically transmembrane)

Question 24

What is an ion channel?

Answer 24

An aqueous channel through the membrane

Question 25

What are to 2 types of ‘gated opening’ ion channels?

Answer 25

• Ligand

- Voltage

Question 26

Can a channel have more than one gated opening?

Answer 26

Yes, Sodium ion channels have a 2 gate system

Question 27

What does it mean by ion channels being selective?

Answer 27

Only a specific ion can pass through that channel

Question 28

What are the 2 gates in the voltage gated sodium channel?

Answer 28

• M-gate

- H-gate

Question 29

When the voltage-gated sodium channel is initially closed. which gate is open and which gate is closed?

Answer 29

• m-gate closed

- h-gate open

Question 30

When the voltage-gated sodium channel is opem. which gate is open and which gate is closed?

Answer 30

• M-gate open

- h-gate open

Question 31

When the voltage-gated sodium channel is closed and in the refractory period. which gate is open and which gate is closed?

Answer 31

m-gate open

h-gate closed

Question 32

Is an action potential an all or none response?

Answer 32

Yes

Question 33

What happens at the ‘threshold’ of the action potential?

Answer 33

• Voltage-gated Na+ channels open
• Na+ diffuse in -> further depolarisation
• Positive feedback involved here

Question 34

What happens at the peak of an action potential?

Answer 34

• Na+ channels close; voltage-gates K+ channels open
• K+ diffuse out -> repolarisation
• Then return to the resting membrane potential

Question 35

When is the M-gate in the Na+ ion channel involved?

Answer 35

• In the first phase through the action potential

Question 36

When is the H-gate in the Na+ ion channel involved?

Answer 36

In the second phase through the refractory period

Question 37

Where are the M and H-gates on the Na+ ion channel located?

Answer 37

Located on the intracellular portion of the channel

this is important if you are going to block the sodium channel - have to do this from the inside of the cell

Question 38

After an AP is initiated, the neuron cannot generate another AP until the first one has ended. What is this period of excitability called?

Answer 38

• The refractory period

Question 39

What is the refractory period due to?

Answer 39

• Due to the inactivation of voltage-gated sodium channels
• The inactivation (‘h’) gates are shut, and so Na+ cannot diffuse into the neuron
• Action potentials cannot add together; they are all-or-none events

Question 40

What are the consequences of a refractory period? (4 points)

Answer 40

• Limits the maximum firing frequency of action potentials in axons
• Ensures unidirectional propagation of action potentials
• Prevents summation of action potentials
• Prevents summation of contractions in cardiac muscle - the cardiac AP lasts as long as the ventricular contraction

Question 41

What does an AP in one section of an axon set up?

Answer 41

Longitudonal direction flow

• This depolarises adjacent ‘resting’ parts of the axons

Question 42

What happens in AP propagation?

Answer 42

• An AP in one section of an axon sets up longitudinal current flow
• This depolarises adjacent ‘resting’ parts of the axon
• The AP is regenerated further along the axon
• More current flows, and the next region of the axon is activated
• AP’s travel along the axon as waves of depolarisation

Question 43

How does an AP travel along the length of an axon?

Answer 43

• Current flows in ICF and ECF from +ve to -ve regions

- This current flow alters the membrane potential in adjacent regions, and the action potential ‘creeps’ along the axon

Question 44

What does the speed of AP propagation increase with?

Answer 44

• Increases with axon diameter

- Large axons conduct impulses more rapidly than small ones

Question 45

What speeds up the process of AP conduction along an axon?

Answer 45

The presence of the myelin sheath

Question 46

Why do axons that are myelinated use more energy?

Answer 46

As the axon will have thousands of Schwann cells - large increas ein the number of cells that need energy

Question 47

What does myelin consist of?

Answer 47

Many layers of cell membranes wrapped round the axon

Question 48

Which type of cells lays down myelin?

Answer 48

Glial cells

Question 49

Myelin forms an insulating layer, what does this do?

Answer 49

Reduces leakage of current from axon

Question 50

The myelin sheath is interrupted at intervals. What are these intervals called?

Answer 50

Nodes of Ranvier

Question 51

What happens at a node of Ranvier?

Answer 51

The axon membrane is exposed to the ECF, and ion flow can occur

Question 52

What is saltatory conduction?

Answer 52

• In myelinated nerve, the passive currents spread further along the axon
• There are fewer regeneration steps per unit length of axon
• Thus, the AP propagates more rapidly that in unmyelinated axons (speeds up the propagation)

Question 53

Peripheral nerves contain many axons. These axons are different in several respects. What are these differences? (2 points)

Answer 53

Size:

• Axon diameter & conduction velocity

Function:

• Sensory, motor

Question 54

Are A-beta fibres myelinated or unmyelinated?

Answer 54

Myelinated

Question 55

Are A-delta fibres myelinated or unmyelinated?

Answer 55

Myelinated

Question 56

Are C fibres myelinated or unmyelinated?

Answer 56

• Unmyelinated

Question 57

What is the function of A-beta fibres?

Answer 57

Mechanoreceptors

Question 58

What are the functions of A-delta fibres? (4 points)

Answer 58

• Mechanoreceptors
• Thermoreceptors (cold)
• Nociceptors
• Chemoreceptors (taste)

Question 59

What are the functions of C fibres? (3 points)

Answer 59

• Mechanoreceptors
• Thermoreceptors (hot and cold)
• Nociceptors