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EPSPs, like IPSPs, are graded (i.e. they have an additive effect). When multiple EPSPs occur on a single patch of postsynaptic membrane, their combined effect is the sum of the individual EPSPs. Larger EPSPs result in greater membrane depolarization and thus increase the likelihood that the postsynaptic cell reaches the threshold for firing an ...
EPSPs on the postsynaptic neuron result from the main excitatory neurotransmitter, glutamate, binding to its corresponding receptors on the postsynaptic membrane. By contrast, IPSPs are induced by the binding of GABA(gamma-aminobutyric acid), or glycine. [4] Synaptic potentials are small and many are needed to add up to reach the threshold ...
The balance between EPSPs and IPSPs are necessary for maintaining neural stability and function. There are many different applications of postsynaptic potentials. Neural Communication and Integration: Postsynaptic potentials allow neurons to integrate inputs from thousands of synapses, functioning as a "decision-making unit" within the brain.
IPSPs can take place at all chemical synapses, which use the secretion of neurotransmitters to create cell-to-cell signalling. EPSPs and IPSPs compete with each other at numerous synapses of a neuron. This determines whether an action potential occurring at the presynaptic terminal produces an action potential at the postsynaptic membrane.
Graded potentials that make the membrane potential more negative, and make the postsynaptic cell less likely to have an action potential, are called inhibitory post synaptic potentials (IPSPs). Hyperpolarization of membranes is caused by influx of Cl − or efflux of K +. As with EPSPs, the amplitude of the IPSP is directly proportional to the ...
The effect of these two options is the hyperpolarization of the postsynaptic cell, or IPSP. Summation with other IPSPs and contrasting EPSPs determines whether the postsynaptic potential will reach threshold and cause an action potential to fire in the postsynaptic neuron.
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Electrotonic potentials which decrease the membrane potential are called inhibitory postsynaptic potentials (IPSPs). They hyperpolarize the membrane and make it harder for a cell to have an action potential. IPSPs are associated with Cl − entering the cell or K + leaving the cell. IPSPs can interact with EPSPs to "cancel out" their effect. [2]