突触连接对快速皮层振荡远程同步的影响。
Effect of synaptic connectivity on long-range synchronization of fast cortical oscillations.
作者信息
Bazhenov M, Rulkov N F, Timofeev I
机构信息
Department of Cell Biology and Neuroscience, University of California, Riverside, Riverside, CA 92521, USA.
出版信息
J Neurophysiol. 2008 Sep;100(3):1562-75. doi: 10.1152/jn.90613.2008. Epub 2008 Jul 16.
Abstract
Cortical gamma oscillations in the 20- to 80-Hz range are associated with attentiveness and sensory perception and have strong connections to both cognitive processing and temporal binding of sensory stimuli. These gamma oscillations become synchronized within a few milliseconds over distances spanning a few millimeters in spite of synaptic delays. In this study using in vivo recordings and large-scale cortical network models, we reveal a critical role played by the network geometry in achieving precise long-range synchronization in the gamma frequency band. Our results indicate that the presence of many independent synaptic pathways in a two-dimensional network facilitate precise phase synchronization of fast gamma band oscillations with nearly zero phase delays between remote network sites. These findings predict a common mechanism of precise oscillatory synchronization in neuronal networks.
摘要
20至80赫兹范围内的皮质伽马振荡与注意力和感官知觉相关,并且与认知加工以及感觉刺激的时间绑定都有紧密联系。尽管存在突触延迟,但这些伽马振荡能在几毫秒内跨越几毫米的距离实现同步。在这项使用体内记录和大规模皮质网络模型的研究中,我们揭示了网络几何结构在实现伽马频段精确远程同步中所起的关键作用。我们的结果表明,二维网络中许多独立突触通路的存在有助于快速伽马频段振荡的精确相位同步,远程网络位点之间的相位延迟几乎为零。这些发现预示了神经元网络中精确振荡同步的一种常见机制。
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