M&R Session 4 (Lecture 4.2)

Question 1

Give 2 examples of diseases that affect the conduction of the AP in the CNS.

Answer 1

1) Multiple sclerosis (all CNS nerves)

2) Devic’s disease (optic and spinal cord nerves only)

Question 2

Give 2 examples of diseases that affect the conduction of the AP in the PNS.

Answer 2

1) Landry-Guillain-Barre syndrome

2) Charcot-Marie-Tooth disease

Question 3

What are the 6 classes of peripheral axons in diameter and conduction velocity order?

Answer 3

1) A alpha (Ia/Ib)
2) A beta (II)
3) A gamma
4) A delta (III)
5) B
6) C (IV)

Question 4

Give examples of function of A alpha, beta, B and C fibres.

Answer 4

A alpha - sensory fibres from muscle spindles, motor neurones to skeletal muslce.

A beta - sensory fibres from pain and temperature receptors (sharp localised pain)

B - preganglionic neurones of ANS

C - sensory fibres from pain, temperature and itch receptors (diffuse pain)

Question 5

How can extracellular recording of an AP be done?

Answer 5

Using an anode and cathode placed on the surface of the cell.

Question 6

Where does the AP start in extracellular recording and why?

Answer 6

At the cathode as the cathode makes the outside membrane potential more negative so it depolarises the inside of the membrane.

Question 7

What is the difference between diphasic and monophasic recording?

Answer 7

Diphasic is where both electrodes are on an intact piece of electrode.

Monophasic is where the B electrode is on a deliberately damaged section of a nerve.

Question 8

Describe the local current theory.

Answer 8

Injection of current into an axon will cause the resulting charge to spread along the axon and cause an immediate local change in the membrane potential.

Question 9

What determines how far a local current spreads in an axon?

Answer 9

The length constant (lambda) which is the distance it takes for the potential to fall to 37% of its original value.

Question 10

What are the equivalent structures of capicitance and membrane resistance in the cell?

Answer 10

Capicitance = lipid bilayer

Mem resis = No. of ion channels open. (lower resis = more channels open)

Question 11

What is the relationship between the length constant, resistance and axon radius?

Answer 11

Lambda = Sq rt (Rm.a/2.Ri)

where Rm = membrane resis and Ri = axoplasm resis

Question 12

Why does the action potential travel in one direction only?

Answer 12

The tissue behind the AP has all of its VGNC closed (therefore in ARP) and are inactivated so no AP can be generated in that tissue. Therefore the AP can only go on the opposite direction i.e. away.

Question 13

Why is the membrane resistance lower behind an AP?

Answer 13

K+ channels are open so the length constant decreases.

Question 14

What does myelination do to the velocity of an AP? How?

Answer 14

Increases the velocity by having a high concentration of Na+ channels at the nodes of ranvier. This is where saltatory conduction takes place so APs are generated at the NoR only.

Question 15

Why is there no point in having a myelinated neurone below 1 micro metre diameter?

Answer 15

Speed would be slower than an unmyelinated one

Question 16

What factors are changed with myelination?

Answer 16

1) 100x increase in Rm
2) 100x increase in Cm
3) Increase length constant
4) Slight decrease in time constant

Question 17

What does demyelination do to the AP?

Answer 17

In regions of demyelination the density of the action current is reduced because of resistive and capacitive shunting.

Failure to reach threshold and stops saltatory conduction.