Action Potential Reading Material Physiology PDF

Summary

This document provides a detailed explanation of action potentials, including resting membrane potentials, the function of the Na+-K+ pump, and stages of action potential. It also discusses conduction along nerve fibers and the role of myelination.

Full Transcript

Objectives

o Discuss the resting membrane potential and its genesis.
o Know the ionic channels involved in resting membrane
potential.
o Describe the function Na+-K+ pump and the stages of action
potential.
o Explain the threshold Potential, local Response and action
Potentials.
o Describe the electrical changes in membrane potential during
the action potential, their chemical bases and excitability
changes.
o Describe conduction along nerve fibers, role of myelination
and how nerve fibers are classified.
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 Resting Membrane Potential of Nerves (RMP):
Transport properties of the resting nerve membrane for sodium and
} RMP: it is the potential difference across potassium:
the cell membrane during rest, without Sodium-Potassium pump (active transport)
stimulation between the inner side and the K+ Leak Channels:
outer side, and it is relatively –ve inside.
} Measurement of RMP: using voltmeter

} Normal Values : -70 in medium sized
nerves and -90 mv in large nerve fibers.
(inside the fiber is 90 times more negative)
} During rest, the membrane is
polarized (the membrane is a wall
between the positive outside and negative
inside)
} There is high molecules of K+ inside the
cell and high molecules of Na+ outside the
cell. Potential: difference in charge across plasma membrane.
Current: flow of charge (ions) from one point to another.

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 Causes (Origin) of Resting Membrane Potential (RMP):
The important factors in the establishment of the normal resting
membrane potential of -90 millivolts. } 2- Contribution of Na diffusion through the
} 1- Contribution of K+ diffusion potential:- nerve membrane:
The cell membrane has tendency to pump potassium (K) Very small amount of Na+ diffuses into the cell (from outside
(positive charge) out, from high to low, (outflux), causing –ve to inside) down its concentration gradient.
charge inside, through K leak channels, down its The membrane is only slightly permeable to Na+ through K-
concentration gradient. Na leak channels.
(producing energy like Niagara falls, from high to low which gives w

energy to Canada)
Result: Electro-positivity outside and electro-negativity inside. } 3- Contribution of the Na+-K+ pump:
RMP is 100 times more permeable to K+ than Na+. This is a powerful electrogenic pump on the cell membrane.
(These K+ leak channels may also leak sodium ions slightly maintains concentration gradients of K+ and Na+ between
but are far more permeable to potassium than sodium) the two sides of the membrane.
K diffusion contributes far more to resting It pumps 3 Na+ to outside & 2 K+ to inside, causing a net
membrane potential. (most important) ‫رﻛز ﻋﻠﯾﮭﺎ اﻟدﻛﺗور‬ loss of +Ve ions from inside, returning the nerve fibre to the
resting state (-4 mV).

5 Remember: Non-diffusible anions (proteins, sulphate, phosphate ions, large molecules) cannot leave the cell. Therefore, they also contribute to the negativity
 Action Potential (AP):
} Nerve signals are transmitted by action potentials, which are rapid
changes in the membrane potential that spread rapidly along the
nerve fiber membrane. Each action potential begins with a sudden
change from the normal resting negative membrane potential to
a positive potential and ends with an almost equally rapid
change back to the negative potential.
} Action Potential: a sudden reverse of membrane polarity (of
charges) produced by a stimulus to produce a physiological effect
such as:
o Transmission of impulse along nerve fibers (transmission of nerve
signals)
o Release of neurotransmitters
o Muscle contraction
o Activation or inhibition of glandular secretion
} Only Excitable tissue (Nerve and muscles) respond to action
potential.
} Firing = excitability = action potential = nerve impulse

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Stages of Action Potential (AP):
1- Resting stage / Initiation 2- Depolarization 3- Repolarization
of Action potential
It is the resting membrane The membrane suddenly becomes K+ outflux through opening
potential before the action permeable to Na+ ions causing Na+ Voltage gated potassium channels,
potential begins. The influx to the interior of the axon this high K conductance (flow) to
membrane is “polarized”. (upstroke) through opening Voltage outside, causes the normal negative
gated sodium channels (positive resting membrane
Initiation: The (polarized) feedback). potential.(Negative inside)
resting membrane potential The membrane charges reverse (more (Na+ channels begin to close and
rises from -90 to 0. (Gradual positive inside) the K+ channels open.)
depolarization) due to Membrane potential rises from 0 to + 35 This channel is slow, which leads to
threshold stimulus. mv, so all Na channels begin to close the next step.
suddenly. à (Depolarization ends)
This channel ends fast.

A state of Hyperpolarization follows repolarization. *Will be explained later*

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 Excitation:
*The process of eliciting the action potential*
} Basically any factor that causes sodium ions to begin to diffuse inward
through the membrane in sufficient numbers can set off opening of
sodium channels. This opening of the sodium channels can result from
mechanical disturbance of the membrane, chemical effects on the
membrane, or passage of electricity through the membrane

Threshold for excitation and “Acute local potentials”
Threshold stimulus:
The membrane potential at which occurrence of the action potential
is inevitable.
When a stimulus is strong enough to move RMP from its resting
value (-90) to the range of -70mV to -55mV (-65 to 55) which leads
to production (start) of an AP or depolarization.
Subthreshold stimulus / Acute subthreshold potential:
Stimulus that results in local depolarization. (local action potential)
(does not propagate or move along).
When stimulus is below the threshold.
All or nothing principle: When threshold value for excitation is
reached, a full Action Potential is produced, so its intensity can not be
increased by increasing stimulus intensity
(suprathreshold).
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Types of Transport Channels Through the Nerve
Membrane
} There are two types:
The voltage gated Na+ channel has two gates:
1. Voltage gated Na+ channels
2. Voltage gated K+ channels.
} What opens the voltage gated channels? A stimulus Has 2 gates
strong enough to depolarize them to threshold.
Activation gate Inactivation gate

on the outer side of on the inner side of
membrane membrane

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 First: The Na+ Voltage-Gated Channel: Has three
states.
1.Resting state 2.Activated state 3.Inactivated state

oThe activation gate is Threshold Depolarizing Stimulus: moves
the MP from its resting value (-90 mV ) to its A few milliseconds after the activation
closed in the resting cell, gate opens, the channel becomes
when the MP* = RMP* is: threshold value (-65 to -55mV)
inactivated: At the peak of AP the
o-70 to -90 mV. This opens the activation gate. inactivation gate will close the inactivation
( NB in this case BOTH the activation gate & gate will NOT open by a second stimulus
üThis prevents entry of à & the cell becomes
Na+ to the interior of the inactivation gate are open ) à permeability to
Na+ becomes increased 500 to 5000 times à Refractory( ‫ )ﻣﻣﺎﻧﻌﺔ‬to another
cell through this gate stimulation
Na+ influx
*Na+ flows into the cell in large amounts* *This goes on until the MP has gone back
to its resting ( RMP) level ( -70 to -
90mV)*
*The activation gate is still open
the inactivation gate is closed*

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What Happens After Action Potential? video
} Refractory period: few milliseconds
Time during which can’t stimulate neuron a second time
Happens until recovery of resting potential
} Two stages:
1. Absolute refractory period:
The period during which a second action potential cannot be
elicited, even with a strong stimulus. (No new action potential
possible).
” ‫“ﯾﻌﻧﻲ ﻣﮭﻣﺎ ﻋطﯾﻧﺎ ﻣﺣﻔز ﺛﺎﻧﻲ ﻣﺎﯾﺳﺗﺟﯾب‬
2. Relative refractory period:
Can trigger new action potential if stimulus is very strong.

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Summary of Action Potential : “EXTRA”

When membrane
potential (mV) reaches
- 70 Na gates will open ,
and the gates will close
when (mV) reaches
+ 30.

K gates will be open
when (mV) reaches
+30 , and close when it
reaches -90.

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 The Neuron
} Definition: Unit of function of the central nervous
system.
1- Soma: cell body
2- Dendrites: carry nerve impulses
from surroundings to soma.
3- Axon hillock: start of action potential
(because it has a lot of voltage gated Na channels)
4- Axon and axon terminal.
Axon with myelin sheath Axon without myelin sheath
Only in male slides:
Myelinated axons diameter: >1um Unmyelinated axon diameter: An Excitable tissue is the tissue
Schwann cells deposit