Sil'kis I G
Institute of Higher Nervous Activity and Neurophysiology, Russian Academy of Sciences, Moscow.
Neurosci Behav Physiol. 1995 Nov-Dec;25(6):462-73. doi: 10.1007/BF02359274.
The use of the method of cross-correlation analysis to elucidate the interactions between simultaneously recorded neurons from various loci of the auditory cortex (AC) and the medial geniculate body (MGB) has made it possible to identify the following characteristics of the functional organization of the excitatory interactions in the thalamocortical neuronal networks: the interdependant impulse action of neurons located at various loci of the AC and MGB was determined by reciprocal excitatory connections; the efficiency of the connections between neurons of the AC, 400-500 microns apart, and between tonotopically associated neurons of the AC and MGB was approximately identical (associations were identified in 12% of the cases); the "divergent" properties of the MGB (AC) neurons were manifested in the fact that one and same neuron could simultaneously excite both neighboring cells and neurons from one or several loci of the AC (MGB); the "convergent" properties of the AC and MGB neurons were manifested in the fact that cells located at various loci of the AC and MGB simultaneously excited one neuron. The results make it possible to explain the deviations observed in the investigation of RF of neurons of the AC and MGB from the principle of tonotopical organization. It is hypothesized that the character of the organization of the excitatory connections in the thalamocortical networks may promote the creation of the necessary conditions for the modification of the efficiency of synapses between all of the elements of the network during the stimulation of individual elements.
运用互相关分析方法来阐明从听觉皮层(AC)和内侧膝状体(MGB)不同位点同时记录的神经元之间的相互作用,使得确定丘脑皮质神经元网络中兴奋性相互作用功能组织的以下特征成为可能:位于AC和MGB不同位点的神经元的相互依赖冲动作用由相互兴奋性连接决定;相距400 - 500微米的AC神经元之间以及AC和MGB的音频拓扑相关神经元之间连接的效率大致相同(在12%的案例中确定有联系);MGB(AC)神经元的“发散”特性表现为同一个神经元可以同时兴奋相邻细胞以及来自AC(MGB)一个或几个位点的神经元;AC和MGB神经元的“会聚”特性表现为位于AC和MGB不同位点的细胞同时兴奋一个神经元。这些结果使得解释在对AC和MGB神经元的感受野研究中观察到的偏离音频拓扑组织原则的现象成为可能。据推测,丘脑皮质网络中兴奋性连接的组织特征可能有助于在刺激单个元件时为改变网络所有元件之间突触效率创造必要条件。