Low threshold calcium spikes, intrinsic neuronal oscillation and rhythm generation in the CNS

Michael J. Gutnick; Yosef Yarom

doi:10.1016/0165-0270(89)90014-9

Low threshold calcium spikes, intrinsic neuronal oscillation and rhythm generation in the CNS

Michael J. Gutnick^*
, Yosef Yarom

^*Corresponding author for this work

Alexander Silberman Institute of Life Sciences

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

34 Scopus citations

Abstract

Field potential studies in vivo have shown that many subcortical structures, such as the inferior olivary nucleus, the thalamic nuclei and the lateral habenular nucleus, generate behaviorally relevant rhythms. In each region, intracellular analysis in brain slices has revealed that activation of a transient, low-threshold calcium current plays a pivotal role in rhythmogenesis. The membrane potential of each individual neuron may oscillate rhythmically as a result of interplay between this current and other inward and outward voltage and calcium-dependent currents. Synchronization of this oscillatory single-cell activity, through mutual interaction and/or appropriately timed afferent drive, results in generation of stereotyped population rhythms.

Original language	English
Pages (from-to)	93-99
Number of pages	7
Journal	Journal of Neuroscience Methods
Volume	28
Issue number	1-2
DOIs	https://doi.org/10.1016/0165-0270(89)90014-9
State	Published - May 1989

Keywords

Inferior olive
Lateral habenula
Low threshold calcium
Neuronal oscillation
Rhythm

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10.1016/0165-0270(89)90014-9

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abstract = "Field potential studies in vivo have shown that many subcortical structures, such as the inferior olivary nucleus, the thalamic nuclei and the lateral habenular nucleus, generate behaviorally relevant rhythms. In each region, intracellular analysis in brain slices has revealed that activation of a transient, low-threshold calcium current plays a pivotal role in rhythmogenesis. The membrane potential of each individual neuron may oscillate rhythmically as a result of interplay between this current and other inward and outward voltage and calcium-dependent currents. Synchronization of this oscillatory single-cell activity, through mutual interaction and/or appropriately timed afferent drive, results in generation of stereotyped population rhythms.",

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AB - Field potential studies in vivo have shown that many subcortical structures, such as the inferior olivary nucleus, the thalamic nuclei and the lateral habenular nucleus, generate behaviorally relevant rhythms. In each region, intracellular analysis in brain slices has revealed that activation of a transient, low-threshold calcium current plays a pivotal role in rhythmogenesis. The membrane potential of each individual neuron may oscillate rhythmically as a result of interplay between this current and other inward and outward voltage and calcium-dependent currents. Synchronization of this oscillatory single-cell activity, through mutual interaction and/or appropriately timed afferent drive, results in generation of stereotyped population rhythms.

KW - Inferior olive

KW - Lateral habenula

KW - Low threshold calcium

KW - Neuronal oscillation

KW - Rhythm

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Low threshold calcium spikes, intrinsic neuronal oscillation and rhythm generation in the CNS

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Keywords

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