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Welcome to the website of the
Southwest Virginia MS Support Group
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Neurotransmitters
Neurotransmitters are small molecules whose function is to
transmit nerve signals (impulses) from one nerve cell (neuron)
to another. Neurotransmitters are chemical messengers which
neurons use to tell other neurons that they have received an
impulse. There are many different neurotransmitters - some
trigger the receiving neuron to send an impulse and some stop
it from doing so.
See this simplified diagram of a neuron:
Nerve impulses always flow in one direction
- from the branched extensions called
dendrites, down the neuron to the
presynaptic terminals. The join between the
presynaptic terminals of one
neuron and the dendrites of another is called
the synapse. The two neurons do not actually touch eachother
but are separated by a space called the
synaptic cleft. When a nerve impulse arrives at a
presynaptic terminal it causes neurotransmitters to be
released into the synaptic cleft. The neurotransmitters then
bind with special "postsynaptic receptors" in the dendrites of
the receiving neuron.
When a postsynaptic receptor receives a neurotransmitter
it can either cause a nerve impulse to travel down the neuron
or it can inhibit a nerve impulse depending on the
neurotransmitter released.
Neurotransmitters which propagate nerve impluses in the receiving neuron are called excitory
neurotransmitters. Those which inhibit nerve impulses are
called inhibitory neurotransmitters.
Neurotransmitters are sythesised in the
cell body (the soma) and migrate down the axon to the
presynaptic terminals. Here they are stored in little packets
called vesicles which fuse with the synaptic membrane. When a
depolarising current (the
action potential) is received, these vesicles release
their contents into the synaptic cleft.
Many different substances effect the
transmission of nerve impulses across the synapse and many of
these are falsely called neurotransmitters. To be a
neurotransmitter a substance must:
be synthesised within neurons
be released from the presynaptic
terminal in response to an
action potential (essentially a nerve impulse).
cause a biological effect in the
postsynaptic receptors. a mechanism must exist to inactivate or
remove the transmitter from the receptor
Neurotransmitters activate receptors by
"sticking" to them and thus preventing other neurotransmitters
from activating them. Inactivation of the transmitter happens
in one of three ways:
reabsorption of the neurotransmitter
into the neuron. This is known as reuptake. destruction of the neurotransmitter with
special chemicals called enzymes. This is known as enzymatic
degradation. by the neurotransmitter becoming
deteched from the receptor and drifting out of the synaptic
cleft. This is known as diffusion.
Substances that effect neurotransmission
but are not neurotransmitters can be broadly divided into two
categories - agonists and antagonists. Agonists make
transmission of nerve impulses more likely. They do this in a
number of ways including preventing reuptake (prozac
and cocaine work this way), actually triggering the receptor
themselves (nicotine works this way) and by making the
receptor more responsive (a lot of anti-anxiety drugs work
like this). Antagonists do the opposite - they interfere with
nerve transmission across the synapse sometimes by blocking
receptor sites (many spider and snake venom work this way) and
sometimes by preventing release of the neurotransmitter from
the presynaptic terminal (many anti-psychotic drugs operate
like this).
The following is an incomplete list of
neurotransmitters, together with the sites in which they work:
Neurotransmitters
Group
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Neurotransmitter
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Region of Operation
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CNS and PNS
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CNS
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Catecholamines
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Neuropeptides
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Endorphins (Enkephalins and Dynorphins),
Substance P
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CNS
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CNS
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Nucleotides
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Adenosine, Adenosine Triphosphate
(ATP)
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CNS, PNS and
ANS
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Nitric oxide
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Nitric oxide
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CNS
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Neurotransmitter links:
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