Synapse physiology-CNs-L4-students - Post-it
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Transcript Synapse physiology-CNs-L4-students - Post-it
Physiology of Synapses in the
CNS- L4
Faisal I. Mohammed, MD, PhD
University of Jordan
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Objectives
Students should be able to:
Define synapse and list the types of synapse
Describe the mechanism of neurotransmitter release
List the major types of neurotransmitters (NT)
Compare the small molecules NT and Neuropeptides
Describe the resting membrane potential and Nernst Equation
Determine the how EPSP, IPSP and Presynaptic inhibition
develops
Describe summation of EPSP and IPSP
Describe the characteristics of synapse (Fatigue and Delay)
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Characteristics of Postsynaptic
Potentials (EPSP and IPSP)
It is a local potential, propagates for a short distance
It is graded potential so it can be summated
It takes 1-2 msec to develop and stays for 15-20
msec
Its amplitude is directly proportional to the strength
of the stimulus (amount of NT)
It is decremental potential (decreases as it travels)
It is due to a change in the permeability of ligandgated (chemically) channels
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Presynaptic Inhibition
Activation of presynaptic synapses decreases
ability of Ca+ channels to open on the
presynaptic terminals.
inhibition of Ca+ influx results in reduced neuronal
excitation
Presynaptic inhibition occurs in many of the
sensory pathways in the nervous system.
The neurotransmitter is usually GABA.
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Comparison between Presynaptic and
Postsynaptic inhibition
IPSP need 1-2 msec to be formed and lasts only
15-20 msec in contrast to presynaptic inhibition
that need 15-20 msec to develop and last longer
than 100 msec sometimes
IPSP leads to changes in the postsynaptic
membrane potential in contrast to presynaptic
membrane potential where it leads to decrease NT
release
Besides all these the site where both work is
different
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Graded Potentials
Small deviations from resting potential of -70mV
hyperpolarization = membrane has become more
negative
depolarization = membrane has become more positive
The signals are graded, meaning they vary in
amplitude (size), depending on the strength of the
stimulus and localized.
Graded potentials occur most often in the
dendrites and cell body of a neuron.
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Graded Potentials
Short-lived, local changes in membrane potential
Decrease in intensity with distance
Their magnitude varies directly with the strength
of the stimulus
Sufficiently strong graded potentials can initiate
action potentials
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Graded Potentials
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Graded Potentials
Voltage changes in graded potentials are
decremental
Current is quickly dissipated due to the leaky
plasma membrane
Can only travel over short distances
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Summation of
Postsynaptic
Potentials
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Summation
If several presynaptic end bulbs release their
neurotransmitter at about the same time, the
combined effect may generate a nerve impulse
due to summation
Summation may be spatial or temporal.
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Summation of Postsynaptic Potentials
Spatial Summation
Excitation of a single presynaptic neuron on a
dendrite will almost never induce an action
potential in the neuron.
Each terminal on the dendrite accounts for about a
0.5 - 1.0 mV EPSP.
When multiple terminals are excited simultaneously
the EPSP generated may exceed the threshold for
firing and induce an action potential.
The rate of firing is directly proportional to the
amplitude of the EPSP
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Summation of Postsynaptic Potentials
Temporal Summation
A neurotransmitter opens a membrane channel for
about 1 msec but a postsynaptic potential lasts for
about 15 msec.
A second opening of the same membrane channel can
increase the postsynaptic potential to a greater level.
Therefore, the more rapid the rate of terminal
stimulation the greater the postsynaptic potential.
Rapidly repeating firings of a small number of
terminals can summate to reach the threshold for
firing.
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Graded potentials in response to opening
mechanically-gated channels or ligandgated channels
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Stimulus strength and graded potentials
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Summation
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Generation of Action Potentials
An action potential (AP) or impulse is a sequence of rapidly
occurring events that decrease and eventually reverse the
membrane potential (depolarization) and then restore it to
the resting state (repolarization).
During an action potential, voltage-gated Na+ and K+
channels open in sequence (Na+ then K+ )
According to the all-or-none principle, if a stimulus
reaches threshold, the action potential is always the same.
A stronger stimulus will not cause a larger impulse.
An action potential is generated mostly at the axon hillock
since it has the lowest threshold compared to the soma or
dendrites.
The axon hillock has the highest density of voltage gated
Na+ channels
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Action Potentials
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Facilitation of Neurons
Often the summated postsynaptic potential is
excitatory in nature but has not reached threshold
levels.
This neuron is said to be facilitated because the
potential is nearer the threshold for firing than normal
but not yet to the firing level.
It is easy to stimulate this neuron with subsequent
input.
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Function of Dendrites in Stimulating
Neurons
Dendrites spaced in all directions from neuronal
soma.
allows signal reception from a large spatial area
providing the opportunity for summation of
signals from many presynaptic neurons
Dendrites do not transmit action potentials.
they have few voltage gated Na+ channels
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Dendrite Function Cont.
Dendrites transmit signals by electrotonic
conduction.
transmission of current by conduction in the fluids
of the dendrites
no generation of action potentials in the dendrites
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Special Characteristics of Synaptic
Transmission
Fatigue
exhaustion of the stores of transmitter in synaptic
terminals.
excitatory synapses are repetitively stimulated at a
rapid rate until rate of postsynaptic discharge
becomes progressively less.
causes areas of nervous system to lose excitability
after a while.
development of fatigue is a protective mechanism
against excess neuronal activity.
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Special Characteristics of Synaptic
Transmission cont.
Post-tetanic facilitation
enhanced responsiveness following repetitive
stimulation
mechanism thought to be build-up of calcium ions in
the presynaptic terminals
build-up of calcium causes more vesicular release of
transmitter
Synaptic delay
the process of neurotransmission takes time, from the
delay can calculate the number of neurons in a circuit
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Synaptic Delay
Neurotransmitter must be released, diffuse across
the synapse cleft, bind to receptor, leads to
membrane potential changes that reaches the
threshold then the postsynaptic membrane
discharges.
Synaptic delay – time needed to do this (0.3-0.5
msec)
Synaptic delay is the rate-limiting step of neural
transmission
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Environmental Changes and Synaptic
Transmission
Effect of acidosis
depresses neuronal activity
pH change from 7.4 to 7.0 usually will induce coma
Effect of alkalosis
increases neuronal excitability
pH change from 7.4 to 8.0 usually will induce seizures
Effect of hypoxia
brain highly dependent on oxygen
interruption of brain blood flow for 3 to 7 sec can lead to
unconsciousness
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THANK YOU