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眨眼条件反射过程中小脑和海马的激活取决于实验范式:一项脑磁图研究。

Cerebellar and hippocampal activation during eyeblink conditioning depends on the experimental paradigm: a MEG study.

作者信息

Kirsch Peter, Achenbach Caroline, Kirsch Martina, Heinzmann Matthias, Schienle Anne, Vaitl Dieter

机构信息

Department of Clinical & Physiological Psychology, University of Giessen, Germany.

出版信息

Neural Plast. 2003;10(4):291-301. doi: 10.1155/NP.2003.291.

DOI:10.1155/NP.2003.291
PMID:15152983
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2565431/
Abstract

The cerebellum and the hippocampus are key structures for the acquisition of conditioned eyeblink responses. Whereas the cerebellum seems to be crucial for all types of eyeblink conditioning, the hippocampus appears to be involved only in complex types of learning. We conducted a differential conditioning study to explore the suitability of the design for magnetencephalography (MEG). In addition, we compared cerebellar and hippocampal activation during differential delay and trace conditioning. Comparable conditioning effects were seen in both conditions, but a greater resistance to extinction for trace conditioning. Brain activation differed between paradigms: delay conditioning provoked activation only in the cerebellum and trace conditioning only in the hippocampus. The results reflect differential brain activation patterns during the two types of eyeblink conditioning.

摘要

小脑和海马体是获得条件性眨眼反应的关键结构。虽然小脑似乎对所有类型的眨眼条件反射都至关重要,但海马体似乎仅参与复杂类型的学习。我们进行了一项辨别性条件反射研究,以探索该设计用于脑磁图(MEG)的适用性。此外,我们比较了辨别性延迟条件反射和痕迹条件反射期间小脑和海马体的激活情况。在两种条件下都观察到了类似的条件反射效应,但痕迹条件反射对消退的抵抗力更强。不同范式之间的大脑激活情况有所不同:延迟条件反射仅在小脑中引发激活,而痕迹条件反射仅在海马体中引发激活。结果反映了两种类型眨眼条件反射期间不同的大脑激活模式。

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