Contribution of intrinsic and synaptic factors in the desynchronization of thalamic oscillatory activity

I. Timofeev , M. Bazhenov , T.J. Sejnowski , M. Steriade
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引用次数: 74

Abstract

The interplay between the intrinsic properties of thalamocortical (TC) neurons and synaptic potentials was investigated in vivo, in decorticated and intact-cortex cats, as well as in computational models to elucidate the possible mechanisms underlying the disruption of the spindle oscillation, a network phenomenon. We found that the low-threshold spikes (LTSs) in TC neurons were graded in their amplitude and latency to peak when elicited by current pulses or synaptic potentials from physiological levels of hyperpolarization. IPSPs could either delay or shunt the LTSs. Although the onset of spindles was rhythmic and did not include rebound LTSs, the end of spindles was highly aperiodic suggesting that desynchronization could contribute to the spindle termination. The desynchronization could have several sources, the main of which are (a) intrinsically generated rebound LTSs in TC neurons that occur with different delays and keep thalamic reticular (RE) neurons relatively depolarized, and/or (b) out-of-phase firing of cortical neurons due to intracortical processes that would result in depolarization of both TC and RE neurons. The present study suggests that an active cortical network participates in disrupting the spindle activities. We propose that the progression of spindles contains at least three different phases, with different origins: (a) the onset is generated by RE neurons that impose their activity onto TC neurons, without participation of cortical neurons; (b) the middle part is produced by the interplay between RE and TC neurons, with potentiation from the cortical network; and (c) the waning of spindles is due to the out-of-phase firing of TC and particularly cortical neurons that participate in the spindle termination.

内在因素和突触因素在丘脑振荡活动去同步性中的作用
研究了丘脑皮质(TC)神经元的内在特性与突触电位之间的相互作用,并在体内、去皮猫和皮质完好猫中进行了研究,并在计算模型中阐明了纺锤波振荡(一种网络现象)中断的可能机制。我们发现,当电流脉冲或生理水平的超极化突触电位激发时,TC神经元的低阈值峰值(LTSs)在振幅和潜伏期上是渐变的。ipsp可以延迟或分流LTSs。虽然纺锤体的开始是有节奏的,不包括反弹的LTSs,但纺锤体的结束是非周期性的,这表明不同步可能导致纺锤体的终止。去同步可能有几个来源,其中主要是(a) TC神经元内在产生的反弹LTSs以不同的延迟发生,并保持丘脑网状(RE)神经元相对去极化,和/或(b)皮层神经元由于皮质内过程的非相放电,导致TC和RE神经元都去极化。目前的研究表明,一个活跃的皮层网络参与破坏纺锤体活动。我们认为纺锤体的进程至少包含三个不同的阶段,它们具有不同的起源:(a)纺锤体的开始是由RE神经元产生的,并将其活动强加给TC神经元,而没有皮质神经元的参与;(b)中间部分由RE和TC神经元相互作用产生,皮层网络增强;(c)纺锤体的减弱是由于TC的非相位放电,特别是参与纺锤体终止的皮质神经元。
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