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excitatorische

Exzitatorische (excitatorische) neurotransmission refers to synaptic processes that increase the probability that a postsynaptic neuron will fire an action potential. These mechanisms typically produce depolarization of the postsynaptic membrane and are essential for enabling information flow within neural circuits.

The principal mediators of excitatorische signaling are excitatory neurotransmitters, most notably glutamate in the central nervous

Excitatorische signaling plays a central role in learning and memory, synaptic plasticity, and development. Long-term potentiation

In neural networks, excitatorische and inhibitory signaling are balanced to shape signal processing. Inhibitory transmission, mainly

system.
Glutamate
acts
on
ionotropic
receptors
such
as
AMPA,
NMDA,
and
kainate
receptors,
and
on
metabotropic
receptors
that
can
enhance
excitatory
signaling.
Acetylcholine
is
another
common
excitatory
transmitter
at
neuromuscular
junctions
and
in
certain
brain
circuits,
acting
through
nicotinic
receptors.
The
net
effect
of
excitatorische
transmission
is
to
generate
excitatory
postsynaptic
potentials
(EPSPs),
small
depolarizations
that
can
summate
over
time
(temporal
summation)
and
space
(spatial
summation)
to
reach
the
threshold
for
triggering
an
action
potential.
(LTP),
a
cellular
mechanism
underlying
memory
formation,
involves
sustained
excitatory
transmission
and
activity-dependent
changes
at
glutamatergic
synapses.
However,
excessive
excitatorische
activity
can
be
harmful,
contributing
to
excitotoxicity
and
neuronal
injury
in
conditions
such
as
stroke
or
traumatic
brain
injury.
mediated
by
GABA
and
glycine,
counteracts
excitation
to
prevent
runaway
activity.
Understanding
excitatorische
processes
is
fundamental
to
neuroscience,
informing
how
information
is
encoded,
transmitted,
and
modified
in
the
brain.