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外周触觉刺激后体感皮层对大鼠小脑外侧半球攀爬纤维反应的影响。

The influence of somatosensory cortex on climbing fiber responses in the lateral hemispheres of the rat cerebellum after peripheral tactile stimulation.

作者信息

Brown Ian E, Bower James M

机构信息

Division of Biology, California Institute of Technology, Pasadena, California 91125, USA.

出版信息

J Neurosci. 2002 Aug 1;22(15):6819-29. doi: 10.1523/JNEUROSCI.22-15-06819.2002.

DOI:10.1523/JNEUROSCI.22-15-06819.2002
PMID:12151562
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6758178/
Abstract

This report describes the temporal relationship between the latency of responses to peripheral stimulation in primary somatosensory (SI) cerebral cortex and the timing of climbing fiber inputs to the lateral hemispheres of the rat cerebellum. Examined in the tactilely responsive regions of crus IIa in the rat, the results show that SI influences the timing of both evoked and spontaneous climbing fiber activity in these cerebellar regions without affecting the rate or probability of complex spike discharge. By reversibly blocking SI activity, we demonstrate that the absence of cortical input results in a lengthening of climbing fiber response latency to peripheral stimuli. Similarly, enhancing the cortical input by subthreshold electrical stimulation of SI results in a shortening of climbing fiber response latency. These results provide a new explanation for the tendency of the inferior olive to oscillate at 7-12 Hz and is consistent with the hypothesis that the inferior olive provides the cerebellum information about the timing of cortical computational cycles. Results are discussed in the context of previous and current hypotheses concerning the physiology and function of the inferior olive/climbing fiber system and are interpreted to provide additional evidence of a role for the cerebellum in the tactile somatosensory system.

摘要

本报告描述了大鼠初级体感(SI)大脑皮层对外周刺激反应的潜伏期与小脑蚓部IIa区外侧攀缘纤维输入时间之间的时间关系。在大鼠IIa腿部的触觉反应区域进行研究,结果表明,SI影响这些小脑区域诱发和自发攀缘纤维活动的时间,而不影响复合动作电位发放的频率或概率。通过可逆性阻断SI活动,我们证明皮质输入缺失会导致攀缘纤维对外周刺激的反应潜伏期延长。同样,通过对SI进行阈下电刺激增强皮质输入,会导致攀缘纤维反应潜伏期缩短。这些结果为下橄榄核倾向于以7-12Hz振荡提供了新的解释,并且与下橄榄核向小脑提供有关皮质计算周期时间信息的假说一致。在先前和当前关于下橄榄核/攀缘纤维系统的生理学和功能的假说背景下讨论了结果,并解释为提供了小脑在触觉体感系统中作用的额外证据。

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