Evidence of slow IPSP in mammalian prevertebral ganglia

R. C. Ma; N. J. Dun; Z. G. Jiang

doi:10.1016/0006-8993(83)90612-1

Evidence of slow IPSP in mammalian prevertebral ganglia

R. C. Ma, N. J. Dun, Z. G. Jiang

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

A short train of nerve stimulation evoked in a portion of neurons of the guinea pig inferior mesenteric ganglia a slow hyperpolarization (slow IPSP) which persisted when the preceding orthodromic spikes were reduced to subthreshold EPSPs by curare, was reversibly abolished in a low Ca solution, and was not blocked by atropine; furthermore, the post-tetanic hyperpolarization induced by direct intracellular stimulation was generally smaller than the slow IPSP evoked by nerve stimulation. The slow IPSP was often associated with a fall in membrane resistance and its amplitude decreased with membrane hyperpolarization. The results indicate that the slow hyperpolarization is a synaptic potential, and differs from the slow IPSP observed in mammalian and amphibian paravertebral ganglionic neurons in that it is atropine insensitive.

Original language	English (US)
Pages (from-to)	350-354
Number of pages	5
Journal	Brain research
Volume	270
Issue number	2
DOIs	https://doi.org/10.1016/0006-8993(83)90612-1
State	Published - Jul 4 1983
Externally published	Yes

Keywords

atropine insensitive
prevertebral ganglia
slow IPSP

ASJC Scopus subject areas

General Neuroscience
Molecular Biology
Clinical Neurology
Developmental Biology

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10.1016/0006-8993(83)90612-1

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title = "Evidence of slow IPSP in mammalian prevertebral ganglia",

abstract = "A short train of nerve stimulation evoked in a portion of neurons of the guinea pig inferior mesenteric ganglia a slow hyperpolarization (slow IPSP) which persisted when the preceding orthodromic spikes were reduced to subthreshold EPSPs by curare, was reversibly abolished in a low Ca solution, and was not blocked by atropine; furthermore, the post-tetanic hyperpolarization induced by direct intracellular stimulation was generally smaller than the slow IPSP evoked by nerve stimulation. The slow IPSP was often associated with a fall in membrane resistance and its amplitude decreased with membrane hyperpolarization. The results indicate that the slow hyperpolarization is a synaptic potential, and differs from the slow IPSP observed in mammalian and amphibian paravertebral ganglionic neurons in that it is atropine insensitive.",

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T1 - Evidence of slow IPSP in mammalian prevertebral ganglia

AU - Ma, R. C.

AU - Dun, N. J.

AU - Jiang, Z. G.

PY - 1983/7/4

Y1 - 1983/7/4

N2 - A short train of nerve stimulation evoked in a portion of neurons of the guinea pig inferior mesenteric ganglia a slow hyperpolarization (slow IPSP) which persisted when the preceding orthodromic spikes were reduced to subthreshold EPSPs by curare, was reversibly abolished in a low Ca solution, and was not blocked by atropine; furthermore, the post-tetanic hyperpolarization induced by direct intracellular stimulation was generally smaller than the slow IPSP evoked by nerve stimulation. The slow IPSP was often associated with a fall in membrane resistance and its amplitude decreased with membrane hyperpolarization. The results indicate that the slow hyperpolarization is a synaptic potential, and differs from the slow IPSP observed in mammalian and amphibian paravertebral ganglionic neurons in that it is atropine insensitive.

AB - A short train of nerve stimulation evoked in a portion of neurons of the guinea pig inferior mesenteric ganglia a slow hyperpolarization (slow IPSP) which persisted when the preceding orthodromic spikes were reduced to subthreshold EPSPs by curare, was reversibly abolished in a low Ca solution, and was not blocked by atropine; furthermore, the post-tetanic hyperpolarization induced by direct intracellular stimulation was generally smaller than the slow IPSP evoked by nerve stimulation. The slow IPSP was often associated with a fall in membrane resistance and its amplitude decreased with membrane hyperpolarization. The results indicate that the slow hyperpolarization is a synaptic potential, and differs from the slow IPSP observed in mammalian and amphibian paravertebral ganglionic neurons in that it is atropine insensitive.

KW - atropine insensitive

KW - prevertebral ganglia

KW - slow IPSP

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Evidence of slow IPSP in mammalian prevertebral ganglia

Abstract

Keywords

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