在大鼠的全脑慢波活动期间,苍白球放电与纹状体活动同时发生。
Globus pallidus discharge is coincident with striatal activity during global slow wave activity in the rat.
作者信息
Goldberg Joshua A, Kats Svetlana S, Jaeger Dieter
机构信息
Department of Physiology, The Hebrew University-Hadassah Medical School, and the Interdisciplinary Center for Neural Computation, The Hebrew University, Jerusalem, 91120, Israel.
出版信息
J Neurosci. 2003 Nov 5;23(31):10058-63. doi: 10.1523/JNEUROSCI.23-31-10058.2003.
Abstract
The emergence of bursting and oscillations in the basal ganglia under normal and pathological conditions has attracted considerable interest, but the neural substrate of these patterns is poorly understood. Here we use multisite recordings in anesthetized rats to examine the relationship of globus pallidus (GP) spiking and striatal activity in relation to cortical slow-wave activity. We found that GP neurons displayed increased spike rates or bursts coincident with cortical activation and striatal up states. Furthermore, the onset of GP bursts typically coincides with transitions to striatal up states that precede striatal spiking. These data indicate that GP activity is driven by excitatory corticosubthalamic input during periods of synchronized bursting activity.
摘要
在正常和病理条件下基底神经节中爆发性活动和振荡的出现引起了相当大的关注,但对这些模式的神经基质了解甚少。在这里,我们在麻醉大鼠中使用多部位记录来检查苍白球(GP)放电与纹状体活动之间的关系,以及它们与皮质慢波活动的关系。我们发现,GP神经元的放电率增加或爆发与皮质激活和纹状体兴奋状态同时出现。此外,GP爆发的起始通常与纹状体兴奋状态的转变同时发生,且该转变先于纹状体放电。这些数据表明,在同步爆发活动期间,GP活动由兴奋性皮质-丘脑底核输入驱动。
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