网络机制在癫痫组织中的快涟漪活动。
Network mechanisms for fast ripple activity in epileptic tissue.
机构信息
Oscar-Langendorff-Institute for Physiology, University of Rostock, Gertrudenstrasse 9, 18057 Rostock, Germany.
出版信息
Epilepsy Res. 2011 Dec;97(3):318-23. doi: 10.1016/j.eplepsyres.2011.03.006. Epub 2011 Apr 5.
Abstract
Fast ripples are high-frequency, 250-600Hz field potential oscillations which can be recorded from hippocampal or neocortical structures. In the neocortex, fast ripples occur during both sensory information processing and under pathological, epileptic conditions. In the hippocampus and entorhinal cortex, fast ripples are exclusively associated with epilepsy and perhaps even mark the epileptogenic focus. In contrast to ripples, which regularly also occur in normal tissue and which are thought to reflect population spike bursts at 100-200Hz paced and synchronised by recurrent inhibition, the fast ripple frequency range exceeds the maximal firing frequency of most neurones. Hence, particularly in the hippocampus, fast ripples must emerge as a network phenomenon and cannot reflect the activity of single spiking neurones. In this review, current views on the mechanisms and processes underlying fast ripples are discussed.
摘要
快涟波是高频(250-600Hz)的场电位震荡,可从海马体或新皮层结构中记录到。在新皮层中,快涟波在感觉信息处理和病理、癫痫状态下都会出现。在海马体和内嗅皮层中,快涟波仅与癫痫有关,甚至可能标志着致痫灶。与涟漪不同,涟漪也经常出现在正常组织中,被认为反映了 100-200Hz 范围内的群体锋电位爆发,由回返抑制同步起搏。快涟波的频率范围超过了大多数神经元的最大放电频率。因此,特别是在海马体中,快涟波必须作为网络现象出现,不能反映单个放电神经元的活动。在这篇综述中,讨论了快涟波背后的机制和过程的当前观点。
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