Lab 2

Question 1

Change in membrane potential during action potential propagation

Answer 1

Simulus gated sodium channels open

Sodium floods into neuron with the opening of more sodium channels

Voltage gate sodium channels close

Voltage gated potassium channels open

Returns to resting membrane prtential and both channels are now closed

Question 2

Define conductance as it applies to ions moving through a cell membrane

Answer 2

Conductance is the inverse of electrical resistance - if the conductance of the membrane is low, then the resistance to movement of that ion across the membrane is high

Depends on permeability (ion channels) and equilibrium potential (driving force)

Question 3

Changes in the membrane potential in a local area of a neuron’s membrane will result from …

Answer 3

changes in membrane permeability

Question 4

Intracellular recordings

Answer 4

Recordings taken from inside of an axon or neuron

measurement of the electrical charge in the internal environment relative to the electrical charge in the external environment outside the membrane

Question 5

Units that are normally used for membrane potential

Answer 5

mV

Question 6

Why does an action potential peak at approximately +40mV?

Answer 6

Because it is going towards sodium conductance

Question 7

Extracellular recordings

Answer 7

Recordings taken from electrodes placed at 2 different points on the outside of an axon or neuron

Records the electrical activity in the external environment of a group of axons such as a whole nerve

Question 8

How do the properties of the individual axons within a nerve vary?

Answer 8

Myelination and diameter

Question 9

Whole nerve potential

Answer 9

An action potential representative of the combined electrical activity of ALL the different axons within a nerve. All individual axons within a nerve summate electrically to produce a WNP

The summed electrical activity from all icons within the nerve

Question 10

What feature in some axons might increase the membrane resistance (rm) and therefore aid in the spread of the electrical signal along the cable?

Answer 10

Myelin

Question 11

Amplitude of WNP is

Answer 11

Phase 1 - upswing

Question 12

2 phases of a WNP

Answer 12

Upswing and downswing

Question 13

Whole nerve action potential is …

Answer 13

biphasic

Question 14

Why is WNP biphasic ?

Answer 14

When you stimulate a whole nerve APs propagate at different speeds along different axons. Some axons are slow and some axons are fast. This means the WNP travels down the nerve as a wave, not a single point, with the APs from the fast neurons at the front and the APs from the slow neurons at the back.The biphasic trace occurs because of the way we record the wave of APs across two electrodes.

Question 15

What is happening within each axon within the nerve during the whole nerve potential?

Answer 15

• If threshold is reached within a neuron, an action potential will propagate along its axon. • Not all neurons have the same threshold.

Question 16

Latency

Answer 16

Time delay between the stimulus and the response

Question 17

Are all the axons doing the same thing at the same time during a WNP?

Answer 17

No - APs propagate at different speeds along an axon according to axon diameter (rin) and the extent of axon myelination (rm)

Question 18

Threshold response

Answer 18

The point at which you first see a response after seeing no response below that threshold on the wave form

Question 19

Maximal response

Answer 19

The point at which increasing the pulse height no longer causes an increase in the amplitude of the response

Question 20

What behaviour did the rat sciatic nerve exhibit in response to increasing stimulation intensity? Was it all-or-nothing? If not, why not?

Answer 20

Increasing stimulation intensity caused more axons within the sciatic nerve to be activated.
• This increased the amplitude of the response.
• In a whole nerve the all-or-nothing response does NOT occur because all axons are not activated at the same time. The all-or-nothing response (action potential) occurs only within individual axons.

Question 21

Subthreshold stimulus - Whole nerve vs single axon

Answer 21

Whole nerve = no response

Single axon = sub threshold response (local potential)

Question 22

Threshold - Whole nerve vs single axon

Answer 22

Whole nerve = First signs of WNP

Single axon = Action potential (all or nothing)

Question 23

Increasing towards maximum response - Whole nerve vs single axon

Answer 23

Whole nerve = WNP increases as the stimulus increases

Single axon = action potential (all or nothing)

Question 24

At maximum response - Whole nerve vs single axon

Answer 24

Whole nerve = WNP is at maximum once all axons within the nerve are activated
Single axon = action potential (all or nothing)

Question 25

Above maximum response - Whole nerve vs single axon

Answer 25

Whole nerve and single axon - same as at maximum response…
Whole nerve = WNP is at maximum once all axons within the nerve are activated
Single axon = action potential (all or nothing)

Question 26

What happened to the second whole nerve/compound action potential ?

Answer 26

The second whole nerve potential progressively decreased in amplitude because the second stimulus occurred during the absolute refractory period in some axons (but not all axons)

The second whole nerve potential eventually disappeared because absolute refractory period was occurring in all axons

Question 27

What physical property of the axons within the whole nerve contributes most to determine the threshold stimulation required?

Answer 27

Internal resistance (diameter) - axons that are able to get to threshold with less ion flux i.e. smaller diameter means that they are more likely to fire action potentials in the same amount of time

Question 28

Wole nerve general trends with stimulation and single axon general trend with stimulation

Answer 28

Whole nerve shows graded response

Single axon nothing until it reaches threshold then all or nothing response

Question 29

Which property of voltage gated sodium channels determines the absolute refractory period?

Answer 29

Inactivation gate – stops channel reactivating too soon. ‘Ball and chain’

Question 30

Velocity =

Answer 30

distance/time

Question 31

mm/ms is the same as

Answer 31

m/s

Question 32

Is the conduction velocity you measured in you rat sciatic nerve the value you might expect in a living rat?

Answer 32

No - different environment, temperature, dying nerves at it is out of the body, handling, preparation

Question 33

Human value of conduction velocity in sciatic nerve approximately

Answer 33

40-100 m/s

Question 34

How does myelination improve conduction velocity?

Answer 34

Increases electrical insulation which increases membrane resistance by reducing current leakage

Question 35

What else, in vertebrate axons, helps conduct electrical signals along the full length of the axon of a large motor neuron?

Answer 35

• Nodes of Ranvier: Gaps in the myelin sheath where regeneration
of AP occurs to improve the
propagation along an axon

Large axon diameter

Question 36

Nodes of Ranvier

Answer 36

Gaps in the myelin sheath where regeneration
of AP occurs to improve the
propagation along an axon.

Question 37

Lignocaine

Answer 37

A local anaesthetic that blocks voltage gated sodium channels

Question 38

Lignocaine and the electrodes

Answer 38

Action potential affected at the second electrode because the sodium channels are affected before this electrode therefore the first potential remained relatively the same and the second potential that occurs at the second electrode slowly decreases in amplitude

Question 39

Lignocaine and what does it influence first?

Answer 39

More active neons are affected first and this is why dentist inject and scratch gums to make pain receptors active therefore are affected by ligonocaine

Question 40

Lignocaine binds to voltage-gated Na+ channels and prevents them from opening. What properties of lignocaine will be important for its local anaesthetic properties compared with, for example, the deadly toxin tetrodotoxin (TTX)?

Answer 40

Lignocaine: Low affinity block - reversible

TTX: High affinity block – not reversible

Question 41

Using the knowledge that you have gained from today’s lab and your lectures, why do you think shellfish poisoning can cause paralysis, and do you think a cure for severe poisoning of this type is possible?

Answer 41

Saxitoxins
• Red tides, reddish dinoflagellates
• Ingested by shellfish then eaten by people
• Causes irreversible poisoning – paralytic shellfish poisoning
• Death due to respiratory failure - blocks the franc nerves which innervates the diaphragm so within minutes that patient can sop breathing

Treatment
• Induced coma/life support
• Wait for insertion of new Na+ channels into cell
membrane

Irreversible blocking of voltage gated sodium ion channels so no more action potential can be propagated

Question 42

WNP is also called a

Answer 42

compound action potential

Question 43

Action potentials propagate more slowly along

Answer 43

small diameter axons compared to larger diameter axons

Question 44

The property of voltage gate sodium channels that determines the duration of the absolute refractory period is the

Answer 44

speed of opening of the inactivation gate

Question 45

Signal filters can be applied to

Answer 45

isolate one signal of interest when the recorded signal contains multiple overlaid frequencies

Question 46

WNP - extracellular or intracellular recording?

Answer 46

Extracellular recording

Question 47

WHat does a WNP represent?

Answer 47

collective response of axons within a nerve

Question 48

WNP varies on both

Answer 48

myelination and diameter of the axons in the nerve

Question 49

Electrodes measure

Answer 49

electrical potentials at a set location