Resting Membrane and action potentials

Question 1

Resting ion conditions of a skeletal muscle cell

Answer 1

inside:
150mM K
15mM Na
0.001 Ca

outside:
5 mM K
150 Na
1 Ca

Question 2

Resting membrane Potential is primarily due to?

Answer 2

the permeability of the Potassium Ions

Question 3

What is the resting membrane potential for some cells

Answer 3

Muscle (cardia/skeletal): -80 to -90
Smooth muscle: -60
Neurons: -60 to -70
Astrogila: -80 to -90
Erythrocytes: -9mV

Question 4

What pumps and channels are important in maintain a resting membrane potential

Answer 4

Na/k ATPase
K leak channels

these are Ion channels that form gated pores

Question 5

Na/K ATPase channel

Answer 5

maintains concentrations in proper place
exchanges 3 Na+ ions to the outside of cell in exchange for 2K+ ions to the inside of the cell

requires ATP

Question 6

K+ leak channels

Answer 6

Open all the time

K+ leak channels are present at 100:1 ration to the Na+ leak channels

Passively move K+ is more likely to leave the cell than Na to enter

allows for K permeabillity to the plasma membrane

Question 7

Forces acting on Ions to develop Membrane Potential

Answer 7

Diffusion forces: Chemical gradients
Electrostatic Forces: Electrical
charge base opposite attracts

These two make up the Electrochemical Forces

Equilibrium potential (Eion) Membrane potential when electrical and chemical forces are equal, no further movement occurs

Question 8

Nerst Equation

Answer 8

61.5/z times the log( [X]out/[X]in)

used to calculate the equilibrium potential

Question 9

Driving Force

Answer 9

Resting membrane potential Vm - Eion

this represents the net efflux

Driving force takes into account the electrical and chemical forces to predict movement of the ions

Question 10

IONin is greater than the IONout
IONin is less thatn the IONout
If IONin is equal to the IONout

Answer 10

the log will be negative

the log will be positive

the log will be zero

Always take into account the ion charge (+/-)

Question 11

At resting membrane why cant NA+ get into the cell if it has an influx driving force

Answer 11

Because the membrane is mostly impermeable to the NA+ at rest

Question 12

Goldman Equation

Answer 12

This is an equation that helps us determine the membrane potential by taking into account all the different ion concentrations and permeabillity

Question 13

What are the three main contributions to the resting membrane potential

Answer 13

Contribution of K+ Diffusion potential: this is the main contributor to resting membrane potential

Contribution of the Na+ Diffusion: very minimal due to low permeability at rest

Contribution of Na+/K+ ATP pump: Indirectly contribution to maintain ion concentration gradients

Question 14

If the Resting membrane potential is more positive, does it make it easier to depolarize?

Answer 14

If the RMP is more positive, it is easier to depolarize because it is closer to the threshold

if the RMP is more negative, it males it harder to depolarize the cell, (hyperpolarized and further away from the threshold)

Question 15

What are some factors that influence the Potassium Distribution that plays an important part in RMP

Answer 15

Enhance cell uptake:
Insulin
B-Catecholamines
Alklosis
Hyperosmolality
Strenous exercise

Impair cell uptake:
A-Catecholamines
Acidosis
External potassium balance
Cell damage

Question 16

Polarization

Answer 16

Deviation from 0 mV

Question 17

Depolarization

Answer 17

when membrane potential becomes less negative

this does not mean action potential because it needs to get to that threshold to get an action potential

Question 18

Hyperpolarization

Answer 18

when the membrane potential becomes more negative

Question 19

Repolarization

Answer 19

when membrane potential is returning towards resting membrane potential

Question 20

Key properties of action potentials

Answer 20

All or None
propagating or self reinforcing
non decremental

Question 21

Graded Potentials

Answer 21

Changes in membrane potential that are small and local
can be both excitatory or inhibitory

Graded potential dissipate with distance because K+ leak channels are always open

Dependant on the stimulus and radius

strength of initiation is correlated with the strength of triggering event

Question 22

Phases of Action Potentials: Resting phase

Answer 22

Phase 4

Question 23

Phases of Action Potentials: Depolarization

Answer 23

Phase 0

Question 24

Phases of Action Potentials: Repolarization

Answer 24

Phase 3

Question 25

Phases of Action Potentials: Hyperpolarization

Answer 25

Refractory period

Question 26

What are the key players in an action potential

Answer 26

Na+ ions
K+ ions
Voltage-gated Na+ channels
Voltage-gated K+ channels
K+ leak channels

Ca+ are important in some cell types

Question 27

How do the Voltage Na+ gates work

Answer 27

Resting: the activation gate is closed and the inactivation gate is open

Activation: the activation gate opens during initial depolarization and Na+ comes into the cell

Inactivation: inactive gate closes rapidly after the inactivation phase after a certain period of time

this inactivation gate will stay closed until the membrane potential returns

Question 28

What is the positive Feedback loop of voltage gated Na+ channels

Answer 28

Local triggering even occurs which opens some channels and if the event is large enough there will be a great wide area of increased membrane potential

more Na+ channels open and more Na+ flows through

this whole process stops at +30 mv because the Na+ channels close

Question 29

What happens during the repolarization phase

Answer 29

Voltage gated Na+ channels are closed

Potassium leaks out still via the K+ leak channels

Voltage gated channels slowly open to further increase the membrane permeabillity to K+

this helps to repolarize the cell

Question 30

What happens during the Hyperpolarization phase

Answer 30

Voltage gated K+ channels stay open a little too long which causes the increased repolarization

THis makes it more difficult to stimulate the next action potential

this is considered the refractory period

Question 31

Absolute refractory period

Answer 31

Na+ channels are either open or the inactivation gate is closed and cannot reopen

Another action potential cannot be generated

(the mountain on the graph)

Question 32

Relative Refractory period

Answer 32

Inactivation gate is now open and activation gate is closed

K+ permeabillity is still fairly high so there is hyperpolarization of the resting membrane potential

Not all Na+ voltage gates are in the same state

An action potential can still happen at this time, but requires a stronger stimulus

Question 33

Hypokalemic Periodic Paralysis (hypoPP)

Answer 33

Periodic dips in blood K+ levels

Drops in blood K+ levels triggers events, but blood K+ levels are normal between attacks

Membrane hyperpolarized, harder to reach threshold
repolarization occurs more quickly

Question 34

Hyperkalemic Periodic Paralysis

Answer 34

Excessive K+ in blood

Prolonged action potential and absolute refractory periods lengthened

these can be managed by mild excersise, potassium wasting diruetics, and glucose consumption