The role of the rat hippocampal cellular electrophysiology in electrogenic cortical epileptic network reorganization
- VernacularTitle:电刺激构建大鼠皮层网络癫痫的海马细胞电生理特征
- Author:
Wang SHENG
1
;
Liu QING
;
Zou ZU-YU
;
Han DAN
Author Information
1. 武汉大学
- Keywords:
epileptic network;
hippocampus;
neocortex;
interspike interval;
tetanization
- From:
Neuroscience Bulletin
2005;21(4):257-265
- CountryChina
- Language:Chinese
-
Abstract:
The purpose of the present work was to study hippocampal cellular electrophysiology involved in cortical epileptic networks reorganized by acute tetanization (60 Hz, 2 s, 0.4-0.6 mA) of the right posterior dorsal hippocampus (ATPDH). Experiments were performed on 35 adult male Sprague-Dawley rats. The ATPDH was used to establish epilepsy model. Four-channel recordings were done simultaneously, two channels for single unit recordings from bilateral hippocampi and other two channels for electrocorticogram (ECoG) or hippocampal electroencephalogram (EEG) recordings on the bilateral sides. The ATPDH bilaterally induced: (1) Epileptic ECoG activities that were originated from single unit afterdischarges of ipsilateral hippocampal neuron, followed by single unit afterdischarges of contralateral hippocampal neuron, finally produced seizure-like oscillations in the contralateral and ipsilateral ECoG. (2) 4-10 Hz rhythmic ECoG oscillations and 100-250 Hz hippocampal EEG oscillations, and asymmetric electrical activities of bilateral hippocampal neurons. (3) The hippocampal neuronal bursting that appeared its interspike interval (ISI) spot distribution in an irregular circular shape. The ipsilateral circular shape ISI distribution was more regular and occurred often, which was time-locked with the sinusoidal pattern of maximum peaks of hippocampal oscillatory trains. The results imply that the epileptic networks are reorganized bilaterally between ECoG and hippocarnpal EEG by the ATPDH. The hippocampal neuronal firing temporally encodes its information, in particular, the irregular circular shape ISI distribution during epileptic network reorganization.
