1a Membrane And Action Potenials

Question 1

What is a membrane potential?

Answer 1

The difference between the voltage inside and outside the neurone

Question 2

What is the resting membrane potential?

Answer 2

-70mV

Question 3

When does movement of ions occur?

Answer 3

When the concentration of ions is different across the membrane

Question 4

What are ion channels?

Answer 4

Permeable pores in the membrane which open and close depending on the transmembrane voltage

Question 5

Which are the four main ions involved in mediating membrane potentials?

Answer 5

Na+ Cl- Ca2+ and K+

Question 6

What is an equilibrium potential?

Answer 6

The equilibrium potential is the potential at which electrochemical equilibrium has been reached - prevents the diffusion of ions down the concentration gradient

Question 7

What equation is used to calculate the equilibrium potential?

Answer 7

Nernst Equation

Question 8

What is the Nernst equation?

Answer 8

E = RT/zF ln (Xintracellular/ Xextracellular)

Where Xin is intracellular ion concentration
z = charge of ion

Question 9

Where is the concentration of sodium ions the highest?

Answer 9

Outside the neurone

Question 10

Where is the concentration of potassium ions the highest?

Answer 10

Inside the neurone

Question 11

Why do membrane potentials not rest at Na/K potentials?

Answer 11

Because the neurone has mixed permeability for both ions

Question 12

What does the size of each ions contribution to membrane potential depend on?

Answer 12

How permeable the membrane is to the ion

Question 13

What does the P in the Goldman-Hodgkin-Katz equation represent?

Answer 13

The permeability / probability of the channel opening so 0 is 100% closed and 1 is 100% open

Question 14

How to increase the membrane permeability for a particular ion?

Answer 14

Open the ion channels

Question 15

What happens when Na+ ion channels are opened?

Answer 15

The membrane potential is shifted in the positive direction (becomes less negative)

Question 16

What happens when K+ ion channels are opened?

Answer 16

Shifts the membrane in the negative direction

Question 17

What is hyperpolarisation?

Answer 17

When the membrane potential becomes more negative than the K+ reversal potential

Question 18

What is the summation effect?

Answer 18

Exitory + inhibitory impulses

Question 19

Why do graded potentials decrease with time?

Answer 19

As they spread down the axon, they decay as charge leaks from the axon and decreases the size of the action potential charge

Question 20

What are the three stages of an action potential?

Answer 20

1. Depolarization
2. Repolarisation
3. Hyperpolarisation

Question 21

Changes in the membrane potential during an action potential are due to what?

Answer 21

Voltage gated ion channels, not pumps - the ions flow out due to diffusion down the concentration gradient which was set up by moving ions via active pumps

Question 22

Why is the resting membrane potential for neurones closest to K- equilibrium potential?

Answer 22

Because the permeability for potassium is greater than sodium

Question 23

What causes depolarization?

Answer 23

The opening of voltage gated sodium ion channels resulting in an influx of Na+

Question 24

What causes repolarisation?

Answer 24

More K+ ion channels opening and K+ flowing out the neurone, returning the potential to be more negative

Question 25

Are the potassium ion channels open during depolarization?

Answer 25

Yes, however not many

Question 26

What is the absolute refractory period?

Answer 26

The period in which it is not possible for another action potential to be generated because the sodium ion channels are inactive

Question 27

How is the membrane resting potential restored after hyperpolarisation?

Answer 27

K+ ions are pumped back into the neurone using an Na+K+ active pump which requires ATP

Question 28

During the upstroke phase of an action potential what is the relative permeabilities of sodium and potassium ions?

Answer 28

Higher permeability for Na+, which results in depolarization

Question 29

Why is the membrane more permeable to Na+ during depolarization?

Answer 29

The sodium ion channels open faster than the potassium ones

Question 30

What are the nodes of ranvier?

Answer 30

Small gaps of myelin intermittently places along the axon which the action potential jumps between

Question 31

What is the type of conduction where the action potential jumps between the nodes of ranvier?

Answer 31

Saltatory conduction

Question 32

What does saltatory conduction do to the speed of the action potential conduction?

Answer 32

Increases it

Question 33

What does the myelin sheath do to the action potential?

Answer 33

Prevents it from spreading as it has high resistance

Question 34

What is known by the all of nothing mechanism of action potentials?

Answer 34

An action potential is only triggered if a certain threshold is reached

Question 35

When does further depolarization stop?

Answer 35

Until the voltage gated sodium ion channels become inactive

Question 36

What type of neurones will have a faster decay?

Answer 36

Small unmyelinated neurones as they have a larger resistance

Question 37

What affect does myelin have on the rate of decay?

Answer 37

Slows the rate of decay and increases the distance of decay along the neurone

Question 38

How does the action potential spread down the neurone?

Answer 38

When sodium enters, it moves a small distance across the inside of the membrane and it’s positive charge depolarizers some more of the membrane, causing more Na+ voltage gated ion channels to open

Question 39

What is propagation along an unmyelinated neurone called?

Answer 39

Continuous conduction

Question 40

Why is continuous conduction slower than saltatory?

Answer 40

Has to spread the whole length of the axon, no nodes of Ranvier

Question 41

Where are most voltage gated channels located?

Answer 41

At the nodes of ranvier

Question 42

What are the two factors which control the conduction velocity inside a neurone?

Answer 42

Myelination and axon diameter

Question 43

What affect does a high axon diameter have on the condition speed?

Answer 43

Increases

Question 44

What other factors influence the conduction velocity?

Answer 44

Cold, anoxia, compression and some drugs

Question 45

What is an axondendritic synapse

Answer 45

Connected to a neuronal dendrite

Question 46

What is an axosomatic synapse

Answer 46

Connected to a neuronal soma

Question 47

What is an axoaxonic synapse?

Answer 47

Connected to a neuronal axon

Question 48

What is paracrine signaling?

Answer 48

Cell produces a signal to cause changes in nearby cells

Question 49

What is autocrine signalling?

Answer 49

Cell secretes an autocrine agent that binds to autocrine receptors on the same cell to trigger a response

Question 50

What type of signalling is found in the neuromuscular junction?

Answer 50

Paracrine signaling

Question 51

What neurotransmitter is used in the neuromuscular junction?

Answer 51

Acetylcholine

Question 52

Which type of receptors are found on the sarcolemma?

Answer 52

nicotinic acetylcholine receptors

Question 53

What is botulism?

Answer 53

When botulin toxin causes the ACh to not be released from the vesicles in the pre-synaptic neurone resulting in muscle weakness

Question 54

What is myasthenia gravis?

Answer 54

Antibodies directed against the nAChR on the sarcolemma, therefore ACh is not detected so less muscle movement

Question 55

What is Lambert Eaton syndrome?

Answer 55

When there are antibodies directed against the voltage gated calcium channels, so no influx of Na+ therefore no action potential

Question 56

What structure is involved in Ca2+ ion storage?

Answer 56

Sarcoplasmic reticulum

Question 57

What happens once ACh binds to nACh receptors on the sarcolemma?

Answer 57

This causes an influx of sodium ions which result in an action potential being propagated down into the T tubules

Question 58

What molecule breaks down ACh?

Answer 58

Acetylcholinesterase

Question 59

How is Ca2+ released into the space surrounding the muscle myofibril?

Answer 59

The action potential is propagated down the t tubules
This causes the DHP receptor to pick up this change in membrane potential and change the shape of the ryanodine receptor which allows Ca2+ influx

Question 60

How is membrane potential measured?

Answer 60

A reference electrode is placed outside the cell, and another is placed inside the cell
The voltage inside and out are measured, and the difference between them is the resting membrane potential

Question 61

what is the extracellular and intracellular concentration of Na+?

Answer 61

Intracellular - 10
Extracellular - 150

Question 62

what is the extracellular and intracellular concentration of K+?

Answer 62

Extracellular = 5
Intracellular = 150

Question 63

What is the definition of flux?

Answer 63

The number of molecules that cross a unit area per unit of time (number of particles).
i.e. molecules.m−2.s−1

Question 64

What three things might cause ion channels to open or close?

Answer 64

transmembrane voltage, presence of activating ligands or mechanical forces.

Question 65

What is the Goldman-Hodgkin-Katz (GHK) equation used for?

Answer 65

To estimate membrane potentials when more than one ion is involved

Question 66

what is the resting membrane potential almost entirely due to?

Answer 66

Resting membrane potential due almost entirely to the movement of K+ ions out of the cell

Question 67

When does an action potential occur from a graded potential?

Answer 67

Action potentials (AP) occur when a graded potential reaches a threshold for the activation (opening) of many Na+ channels resulting in an “all-or-nothing” event

Question 68

What happens to the activation and inactivation gates during the process of repolarisation?

Answer 68

start: activation: open, inactivated: close

later: both closed

Question 69

What happens during the relative refractory period?

Answer 69

Some Na+ channels have recovered from inactivation – gate is open