Neurons Practise Questions 2023-10-10 - Tagged.pdf

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Neurons: Practise Questions
Dr. Harry Witchel
Questions or comments?
Contact: [email protected]

1

Core Memorisation

2

What is the clinical importance of
measuring conduction velocity?
• This is measured to investigate the source of motor
weakness in arms and legs.
• It can detect gross pathological changes such as
conduction block and
conduction
Click
to see answerslowing, which could
signify demyelination or degeneration.
It can help diagnose: Peripheral neuropathy, Carpal tunnel
syndrome, Spinal disc herniation, etc.
3

Draw a graph of a neural action potential.
Include axes (and their labels), units, and
approximate numerical values.

DEP
O

LAR
ISAT
ION

OVERSHOOT
IO
ARISAT
REPOL
N

• AP should last 2-4 ms.
RMP should be between
-85 mV and -55 mV. The
AHP should go negative
to the RMP, but it should
remain slightly above -90
answer
mV (EK). Overshoot Click to see THRESHOLD
should peak between 0
and +40 mV.

RESTING STATE

Hyperpolarization

4

For each of those phases of the action
potential: list the ionic current (and the ion’s
direction of movement) that is responsible.

•
•
•
•
•

Resting membrane potential is determined primarily by K+ moving down its
concentration gradient (leaking out of cell), leaving behind negative anions inside
membrane. This is due to leak and some inward rectifier currents.
Depolarisation is due to Na+ rapidly coming into the cell.
The threshold is the voltage above which the cell is committed to completing an
action potential. It occurs when inward Na+ current depolarizes the cell faster than
outward K+ current can repolarise the cell back to the RMP.
Repolarisation is due to Na+ channels inactivating while K+ is rapidly leaving the cell
via the delayed rectifier channels.
is see
NOTanswer
the Na/K pump, which only changes Vm
ClickItto
by 3 mV.
The afterhyperpolarisation is when Vm is most close to EK at the end of the AP.
Many different sources of K+ permeability cause K+ to flow out: inward rectifiers,
leak, and delayed rectifiers (which are delayed in their closing). In addition, during
the AHP unusually little Na+ is flowing because the Na+ channels are inactivated
(which occurs after a delay when Vm is above -40 mV)

5

Name the main transmembrane
forces on an ion.

• Chemical (diffusional) and electrical
Click to see answer

6

What is a graded potential?
• It is a change in the membrane potential that is NOT an
action potential. It can vary in voltage amplitude and in
time duration. A graded potential is not amplified, and it
is not all-or-none.
• It can occur at receptor cells (eg rods and cones) where
Click to see answer
it is important in transduction
of light/pressure into a
graded electrical potential
• Also occurs at synapses.
Graded potential
Action potential
7

What is a refractory period?

• A refractory period is a time duration after one action
potential has just fired when another action potential
either cannot (absolute refractory period) is resistant to
(relative refractory period) restimulation to begin a new
action potential. It often
associated
with Vm being
Click tois
see
answer
lower than the RMP (the after-hyperpolarisation), and it
is usually caused by a high permeability to K+ (i.e. more
K+ channels are open than at rest).

8

What is an equilibrium potential?

• It is the voltage where the amount of a particular ion
(e.g. Na+) flowing out of the cell = the amount of that ion
flowing in. It happens when the electrochemical forces
for that ion type are in equilibrium.
Click to see answer
• E.g. For Na+, this occurs when the diffusion (chemical)
forces pushing Na+ into the cell equal the voltage
(electrical) forces pushing Na+ out of the cell

9

Draw a diagram showing the two forces
on K+ ions at its equilibrium potential.

• EK = -90 mV
• At the equilibrium potential
the chemical force driving
K+ ions out of the cell (black
Click
to see answer
arrow) is equal and
opposite
to the electric force pulling
the K+ ions into the cell
(grey)

K








K -90 mV





K

K
K
K
K K
K K
K K
K
K



10

Name the equilibrium potentials for
Na+, K+, Ca2+ and Cl¯ (in a typical
cell).
•
•
•
•

ENa = ~ +55 mV (or you could say +60).
EK = ~ -90 mV
ECa = ~ +123 mV
Click to see answer
ECl = ~ -40mV (although this varies by cell type
and is sometimes quoted as being -65 mV)

11

Why is the resting membrane
potential -70 mV when there are so
many positive K+ ions inside the
cell?
•

•

Resting membrane potential is determined by which ion has the most
conductance. Because at rest K+ is by far the most conducted ion, the
high K+ that is leaking out of the cell leaves behind negative ions (esp.
proteins and Cl-). The fact that there are so many K+ ions inside the cell
does not make the inside positive because virtually every single one of the
K+ ions is balanced by a negative charge (proteins & Cl-) right next to it.
Click to see answer
Extra credit: formally, the instantaneous membrane potential is determined
as a weighted average of the ionic equilibrium potentials of all ions, where
the weighting is determined by the relative conductance of each ion.
Because at rest the conductance of K+ dwarfs the conductance of any
other ion, the resting membrane potential moves toward EK, which is -90
mV.

12

Give two examples of drug classes
that block sodium channels as part
of their mechanism of action.
• Local anaesthetics (eg lidocaine). Some
anticonvulsants (eg carbamazepine). Type I
Click to see
answer(eg quinidine,
cardiac antiarrhythmic
drugs
phenytoin and lidocaine (which is also classed
as a class Ib antiarrhythmic).

13

Name three all-or-none physiological
phenomena characterised by
positive feedback. Hint: many
examples are in the
endocrine/reproductive systems
from A levels.
• Parturition (giving birth). Menstrual cycle
(ovulation). Vomiting. The action potential.
Blood clotting cascade.
Click to see answer

14

Draw a diagram showing how
depolarisation is a positive feedback
loop.
Vm
becomes
more +

Vm moves toward
E(Na)

+
Small Na+ current
POSITIVE
inward
FEEDBACK
Click to see answer

Membrane potential (Vm)

Perturbation:
Vm becomes more
positive
If Vm goes above
threshold

Some Voltagesensitive Na+
channels open

15

Name two kinds of synapses.

• Chemical synapses, electrical synapses. Also
inhibitory and excitatory.
Click to see answer

16

What is the conduction velocity for
an alpha motor neuron?
• 100 meters/second
Click to see answer

17

What is the conduction velocity for
C fibres for pain?
• 1 meter/second
Click to see answer

18

What are the structural differences between
alpha motor neurons and C fibres responsible
for the difference in their conduction velocity?
Explain which structural features increase and
which decrease conduction velocity.
• Alpha is large diameter and myelinated, both of
which increase conduction velocity.
• Myelination increases transmembrane resistance,
which leads to more efficient electrotonic
signalling inside the axon between nodes of
Click to see answer
Ranvier.
• Increased diameter leads to increased conduction
velocity because intracellular resistance along the
length of the axon is lower. This leads to more
efficient (hence faster) electrotonic transmission.
19

Why do neurons with a larger cross
sectional diameter conduct faster?
•

Larger diameter means that along the length of the intracellular fluid of the axon
there is less resistance and higher conductance.

•

Using the river rapids metaphor, a wider river (higher conductance) leads to more
flow (current) for the same drop in height (voltage)

•

to see
Extra credit: Lower resistanceClick
implies
less answer
voltage drop as the signal is conducted
down the length of the axon.
Extra credit: What this means is that as the current is electrotonically conducted
down the length of the axon, more current travels down the axon and less current
crosses the membrane. This has the effect of creating larger electric fields the
further downstream from the initial stimulus you are. Larger electric fields speed up
conduction because at downstream points the increased voltage will open more
Na+ channels and allow the downstream part of the axon reach threshold faster.

•

20

Remember: current can be transmitted along
the inside of the axon or cross the membrane
•

Most current will follow the path of least resistance.

•

If you lower the resistance inside the axon, a greater
% of the total current will go that way.

•

Any current transmitted along the axon will move the
local voltage away from the RMP.

•

Any current that goes across the membrane will
diminish the signal going down the axon.
–

•

-10

-20

-30

-40

-70

So locally the voltage will stay near the RMP

Voltage signals diminish as you go farther from the
source
–
–

This happens because the axon has a finite resistance
When current meets resistance, it dissipates the
voltage

21

Why does myelination lead to
increased conduction velocities?
• Myelination increases the transmembrane resistance
and decreases the transmembrane capacitance.
• Extra credit: increased transmembrane resistance
Click to see
means that more current
willanswer
flow down the length of
the axon’s intracellular fluid (as opposed to cross ing
the membrane). Decreased transmembrane
capacitance means that any accumulation of charge
across membrane leads to a greater change in Vm.
22

What are the Nodes of Ranvier and
what is their purpose?
• The nodes of Ranvier are thin, unmyelinated strips of
membrane along the length of a myelinated axon.
• The nodes are excitable, the axon under myelin is not

– The nodes have clusters of Na+ channels
– The “bare” cell membrane at the node is specialised for
detecting a distant transmembrane electric field (electrotonically)
and then firing an action
in response to it.
Click potential
to see answer

• Nodes of Ranvier are essential to increasing conduction
velocity by having action potentials “jump” from one node to
the next – so-called saltatory conduction.
• Electrotonic transmission is much faster than starting an
action potential, but electrotonic transmission is limited by
distance because the signal gets smaller as it travels further
from its origin

23

Give an example of a local
anaesthetic and explain how they
work.
• Lidocaine (lignocaine). These block sodium
channels, which raises the threshold of action
Click to
see answer
potentials and thus
lowers
local excitability

24

How are electrical synapses
molecularly coupled?
• Via gap junctions
Click to see answer

25

Name 5 ways by which chemical and
electrical synapses differ. (do not
include duplicate or trivial
observations)
• Electrical synapses are: faster, bidirectional,
10-fold thinner gap, no amplification, no
Click to
answer
plasticity (and thus
noseelearning)
*E

26

What is the velocity of blood in a
capillary?
• 0.5 mm/second
Click to see answer

27

What is the velocity of a person
walking?
• ~1 meter/sec
Click to see answer

28

Give an example of a selective
serotonin reuptake inhibitor and
explain how they work.
• SSRIs include well-known antidepressants such as
fluoxetine (Prozac), paroxetine, citalopram and
fluvoxamine.
Click to reuptake
see answer of serotonin from the
• SSRIs block the normal
synaptic cleft, so serotonin builds up in the cleft,
leading to a change in serotonin signalling

29

Conceptual Knowledge

30

What would happen if the membrane
suddenly became 100X more
permeable to Cl¯ ions than to any
other ion? Why?
• The membrane potential would become clamped to
ECl (e.g. -65 mV) because the chloride current would
swamp out all other
ionic currents (due to its
Click to see answer
comparatively high permeability).

31

What is the velocity of blood in the
aorta?
• ~1 meter/second
Click to see answer

32

What would happen if the membrane
suddenly became 100X more
permeable to Na+ ions than to any
other ion? Why?
• The membrane potential would become clamped to
ENa (i.e. +55 mV) because the sodium current would
swamp out all other
ionic
currents
Click
to see
answer (due to its
comparatively high permeability).

33

How does sodium channel inactivation affect
sodium channel activity during the following
phases of the AP: rest, depolarisation,
repolarisation, after-hyperpolarisation?
•
•
•
•
•

Inactivation interferes with Na channel conduction after the membrane has been depolarised
(but with a delay). It affects the AP as follows:
Rest – no effect, the membrane has not and is not depolarised
Depolarisation – no effect, the membrane has not and is not depolarised
Repolarisation – reduces Na+ conduction massively because, the membrane has been
depolarised. Allows faster repolarisation
by K+ conductance
Click to (mediated
see answer
After-hyperpolarisation – initially reduces Na+ conduction massive because the membrane
has been depolarised, but over time recovery from inactivation occurs because the
membrane is not depolarised.

34

How do neurons encode intensity of
a signal?

• Increased frequency, or different neurons for
different signal strengths
Click to see answer

35

What is the definition of Na+ channel
inactivation? What will happen to the
excitability if the cells are held in a
slightly depolarised state?
•

Channel "INactivation" is the process whereby depolarisation of the membrane
leads to reduced (or eliminated) channel conductance; keep in mind that
"activation" (of voltage gated Na channels) is when depolarisation leads to
increased conduction. Na+ channel inactivation means that as the membrane
remains slightly depolarised (eg during low level stimulation at synapse), the
ability of the Na channel to conduct
compromised,
Click toissee
answer such that even if the
membrane is further depolarised (by greater synaptic activity), it is harder to reach
the threshold where the positive feedback of action potential depolarisation can
begin. a raised threshold means lower excitability.

36

If a neuron was regularly being stimulated
but to a subthreshold potential, would it be
possible for a subthreshold stimulus onto
that neuron via a different synapse to cause
an action potential? Why? What is this
issue called?
• The phenomenon where two different inputs to a
neuron, which are both subthreshold, lead to an action
potential is called spatial summation. What happens is
that each stimulus partially
depolarizes
the membrane
Click to see
answer
when creating the EPSP. Each increase in voltage
takes that part of the membrane closer to threshold.
37

Define convergent signalling and
give an example where it occurs.

• Convergent signalling is when inputs from
multiple neurons converge upon a single
neuron, so often there are multiple inputs
leading to a single
“processed”
output.
Click
to see answer
Examples are everywhere in the nervous
system and include: sensory organs (eg retina
and cochlea), the thalamus, the basal ganglia

38

At the resting membrane potential,
which force is stronger: the chemical
(diffusional) force on K+ ions, or the
electrical force on K+ ions? Explain.
• At the RMP the chemical force on K+ is 90 mV
outward (as it always is), while the electrical
force on K+ is ~80
so the chemical
Click mV
to seeinward,
answer
force is slightly stronger.

39

What would happen to the resting
membrane potential if extracellular
Na+ suddenly increased? Why?
• Not much would happen to the resting
membrane potential if extracellular Na+ went
up a bit, because the RMP is mostly dependent
Click to
see answeris that ENa (driving
on K+. What would
happen
Na+ into the cell) would become more positive,
and the RMP might become slightly less
negative.
40

What would happen to the resting
membrane potential if extracellular
K+ suddenly increased? Why?
• If extracellular K+ suddenly increased, EK driving K
outward would be reduced (ie become less negative).
Because EK is the major determinant of the RMP, the
RMP would become less negative.
Click to see answer

• Extra credit: However, this depolarisation paradoxically
leads to Decreased excitability (not increased, as
predicted) because the long term depolarisation
inactivates Na+ channels, so it is harder to reach
threshold
41

Give two examples where graded
potentials occur that have
physiological effects.
• Sensory receptor cells (retina, cochlea, taste
buds, etc). Synapses.
Click to see answer

42

Why don’t graded potentials
propagate long distances?

• Graded potentials diminish over distance
because voltage approaches zero as it travels
along a resistor – and all biological fluids (and
to see answer Graded
membranes) act Click
as resistors.
potentials (unlike action potentials) are not reamplified and restored.

43

Name 5 ways action potentials
differ from graded potentials.
• Action potentials are: Fast. All-or-none. Amplified. Can
travel long distances. Spiky. Stereotyped voltage
changes. Last a consistent duration of time
• Graded potentials are: Electrically localised. Slow to
to see answer
return to the resting Click
potential.
Variable in voltage.
Variable in duration. Much Flatter. Decreased in
voltage as they move. Conduct quickly

44

Why do axons need action potentials
(rather than graded potentials) to
propagate signals long distances?
• Because action potentials restore and re-amplify
signals, so that those electrical signals can travel with
fidelity (ie without loss of voltage or information) down
long lengths of axon. A small receptor cell (eg rods and
cones) can afford toClick
have
receptor
to see
answer potentials that are
graded potentials because those cells do not send
signals long distances inside that cell – they send their
signals long distances by transferring the information to
another neuron which will use action potentials.
45

Do K+ ions move across the
membrane at the equilibrium
potential for K+, and why?
• Yes. K+ ions will move back and forth,
although the net movement at the equilibrium
potential will be nil because the numbers
moving in will be the same as the numbers
Click to see answer
moving out, which happens because the forces
on K+ (electrical and chemical) will be equal
but opposite.

46

Draw a negative feedback diagram
showing how the electrochemical
force on K+ varies to maintain the
resting membrane at the resting
membrane potential.
• This has been uploaded to Student Central as
a separate powerpoint file.
Click to see answer

47

Subtleties of conceptual knowledge

For advanced students to test high
level comprehension of these concepts

48

Why is it impossible for an electrical
synapse to transmit forward a signal
if the post-synaptic cell is much
bigger than the pre-synaptic cell?
• Electrical synapses allow for a direct electrical connection between
the two cells (using gap junctions). This means that the
connection between the two cells includes a resistance and a
capacitance. A problem arises if the presynaptic cell is electrically
small compared to a larger post-synaptic cell because 1)
potentials are reduced as they are communicated along the length
of a resistor, and 2) theClick
post-synaptic
cell acts as a capacitor, and
to see answer
if the pre-synaptic cell is small, the finite charge it communicates
will “be absorbed” by the larger capacitance of the post-synaptic
cell, i.e. the potential differences the pre-synaptic cell induces will
be smaller in the cell with a larger capacitance than it has. So
although it may communicate the electrical signal, the larger
capacitance in the post-synaptic cell will make the change smaller.
49

What does the Nernst equation
calculate?
• The relationship between the chemical diffusional
force caused by an ionic gradient, and its equivalent
electrical force. It formally calculates the equilibrium
potential, which is Click
the voltage
when there is no net
to see answer
current mediated by a particular ion because the
chemical and electrical forces balance.

50

What would happen if “delayed
rectifier” K+ channels were not
“delayed”, i.e. these K+ channels
opened immediately upon
depolarisation?
• When K+ channels open, Vm moves toward EK, which is how the
action potential normally repolarises. The timing of the action
potential is such that the delayed rectifier channels open AFTER
depolarisation has taken place. It is difficult to say whether the
delayed rectifier K+ currents at their peak are larger than the
depolarising Na+ currents at their peak (because the Na+
currents always inactivate
the K+ currents can be
Click before
to see answer
compared to them). However, if the K+ channels open
immediately (ie simultaneously with the Na+ currents of
depolarisation), the depolarisation would definitely be slower and
smaller, if it occurred at all.
51

Name 5 ways to initiate a subthreshold
stimulus in a neuron that might lead to
an action potential.
• EPSP from a synapse, an electrical signal
from a nearby part of the same neuron (which
travels as a graded potential), a signal via an
Click to
answer cell transducing
electrical synapse,
a see
receptor
a stimulus (eg light hitting rhodopsin), a
change in extracellular ion concentration (e.g.
an increase in extracellular K+)
52

During the after-hyperpolarisation, Vm
becomes more negative than the RMP.
Why?
• The RMP approaches (but but is slightly more positive than) EK.
Compared to the RMP, Vm during the AHP is driven more
negative by:
• An increased K+ current due to the delayed rectifier (because
there is a time delay for the channels to close after repolarisation)
• A decreased Na+ current
(because
Na+ channels will still be
Click
to see answer
inactivated from the previous depolarisation due to a time delay)
• An equivalent amount of inward rectifier K+ current outward (ie
inward rectifier has almost no delay and is dependent on negative
voltage to open, which is true during both AHP and during RMP)

53

The nicotinic acetylcholine receptor is a ligand-gated non-selective
cation channel, which means that when it is in the presence of
acetylcholine, it will act as an open ion channel that conducts both
Na+ and K+. If you assume that when it is open it is equally permeable
to Na+ and K+, what would be its equilibrium potential. Explain this in
terms of conductances and equilibrium potentials of various ions.
• If you assume that the channel has equal permeability to Na+ and
K+ (actually it is not quite equal), then the equilibrium potential for
the channel would be the voltage directly between the EK (-90
mV) and ENa (+55 mV). This is because the net voltage across a
membrane is the weighted average of the equilibrium potentials,
where the weighting is based on the conductances (i.e. if there is
more conductances for K+ when the cell is at rest, then the
resting membrane potential
will
beanswer
close to EK). In this case, if
Click to
see
the conductances for the two ions is equal, the net voltage would
be the voltage directly between +55 and -90 is -17.5 mV. You can
calculate this via: -90 + ((55 + 90)/2).
• In actual fact, the equilibrium potential for the nAChR is ~ 0 mV,
because the permeabilities are not exactly equally balanced.

54

Some diuretics used for hypertension (e.g. non-K-sparing diuretics such as
thiazides) cause a net loss of blood K+ via urinary excretion. What would you
expect to happen to neural resting membrane potentials, EK, AP thresholds,
and excitability in moderate hypokalaemia? It turns out that moderate
hypokalaemia leads to muscle weakness and myalgia, and severe
hypokalaemia leads to flaccid paralysis. Does this clinical picture fit with what
you know about action potentials?

• Hypokalaemia would mean that there is less
extracellular K+ (but the same amount of
intracellular K+ initially). This would mean that the
driving force pushing K+ out of the cell would be
greater, and that EK would be more negative. That
would make the resting potential more negative,
see answer more negative.
and it would makeClick
thetothreshold
All this would lower excitability. Muscle weakness
and flaccid paralysis would be the results of
slightly and greatly diminished excitability,
respectively.

55

Imagine that there is a drug, and at the dosage you administer that drug, it has
side effects. The drug blocks half the K+ current (both delayed and inward
rectifiers) but it upregulates the Na/K pump such that its activity is doubled.
What would you expect to happen to the resting membrane potential and to
the action potential? Draw a very approximate neural action potential under
the influence of this drug, and compare this action potential to a normal neural
action potential. In your action potential drawings, include axes, axis labels,
units and approximate values.

• If the K+ current is half blocked, the resting membrane
potential will not be as close to EK – it will be depolarized,
possibly by as much as half. By contrast, if the Na/K pump
activity is doubled, its electrogenic effects will be double.
However, the electrogenic effects only hyperpolarise the
membrane by 3 mV, so the resting membrane potential will
be an additional 3 mV more negative. However, the effects on
K+ channels will haveClick
a very
strong
effect on the RMP. One
to see
answer
might imagine that the RMP will move up toward ECl –
possibly going as high as -65 mV. In addition, because the
delayed rectifiers are half blocked, the repolarisation of the
AP will be delayed, and the AP will become wider in duration.

56

If Nodes of Ranvier speed up
conduction velocity via saltatory
conduction, would increasing the
space between nodes lead to much
faster conduction?
• Up to a point, increasing the inter-nodal distance will
increase conduction velocity, but if the nodes were too
far apart, there would be no conduction because the
downstream node would not fire an action potential.
Click to see answer
The further apart two
nodes are, the more potential
difference (in voltage) will diminish along the length of
the axon, making it less likely that the next node will
reach threshold based on the conduction of the electric
field from the previous node.
57

The conduction of a signal along an axon is accelerated if the axon is
wider. Explain this in terms of resistances, capacitances and graded
potentials. The conduction is made even faster by myelination.
Explain this in terms of resistances, capacitances and graded
potentials.
•

•

Resistance determines where currents go (toward the lower resistance). As current and
charge (the graded potential) goes along the length of an axon, the current has a choice of
going further along the axon, or across the axon membrane. If the current goes across the
axon membrane, that reduces the transmembrane potential. If the transmembrane potential is
reduced that means the next segment of the membrane is less likely to fire because the ion
channels of the AP are triggered by the electric field of the previous bit of axon. Ultimately
they will fire, but later, which makes conduction more slow. When the cross-sectional area
inside the axon becomes larger, it makes the internal resistance smaller, so more current will
travel along the axon as opposed to crossing the membrane. Hence the signal will travel
faster.
Capacitance is the ability to maintain
separation
Clickcharge
to see
answer(and thus electric fields). Myelin
increases capacitance (and vastly increases the resistance across the membrane). As such,
myelin sustains the electric field across the membrane and prevents dissipation of charge
across the membrane. The graded potentials traveling along the length of the myelinated
axon are strong and have enough electric field to trigger Na+ channels to open at a long
distance (the next node of Ranvier). As electric fields travel instantly (while it takes time for a
new action potential to amplify the signal), in effect myelin allows the AP to jump from one
node to the next, which greatly speeds up conduction.

58

If during the relative refractory period Vm is more negative than at rest,
which means more driving force for sodium, would it be easier to fire
an action potential (ie would excitability be increased during the
relative refractory period)?

•
•
•
•

•
•
•

No.
Excitability is determined by how easy it is to depolarise the cell to the threshold potential.
HOWEVER, the threshold potential is NOT always the same — it can be changed by
interfering with the balance of K+ and Na+ currents.
The threshold condition (ie the threshold potential) is the potential at which the inward current
via voltage-gated Na+ channels just exceeds the total outward current (mostly via K+
channels). When voltage-gated Na+ current (which makes the membrane more positive and
thus opens more Na+ channels) exceeds outward current, a positive feedback cycle begins,
making full depolarisation inevitable.
During the absolute refractory period,
Na+answer
channels are inactivated, reducing Na+
Clickmany
to see
channel current, so the threshold voltage becomes impossibly high because there are not
enough Na+ channels capable of conducting to reach the threshold condition.
During the relative refractory period, most Na+ channels have recovered from inactivation, but
there remains high outward K+ current (compared to at rest). This excess outward current
makes it harder to reach the threshold condition.
Thus despite the increased Na+ drive during the relative refractory period, the increased K+
outward current (making threshold voltage higher) is the dominant effect during the relative
refractory period.

59