Hirsch Judith A
Department of Biological Sciences and Neurosciences Graduate Program, University of Southern California, Los Angeles, CA 90089-2520, USA.
Cereb Cortex. 2003 Jan;13(1):63-9. doi: 10.1093/cercor/13.1.63.
How does the cortical circuitry analyze the visual scene? Here we explore the earliest levels of striate cortical processing: the first stage, where orientation sensitivity emerges, and the second stage, where stimulus selectivity is further refined. The approach is whole cell recording from cat in vivo. Neurons in the lateral geniculate nucleus of the thalamus have circular receptive fields whose subregions, center and surround are concentrically arranged and have the reverse sign, on or off. These neurons supply cortical simple cells, whose receptive fields have on and off subregions that are elongated and lie side by side. Feedforward models hold that orientation sensitivity depends on this thalamocortical change in receptive field structure and an arrangement within subregions such that stimuli of the reverse contrast evoke synaptic responses of the opposite polarity-push-pull. Our work provides support for feedforward models and emphasizes that push-pull is key in the geniculostriate pathway, preserved from retina by thalamic relay cells and reiterated, point by point, by cortical simple cells. Also, we help define the cortical push-pull circuit by identifying inhibitory simple cells. Lastly, separate experiments that compare the first and second levels of cortical processing suggest that differences in the synaptic physiology of connections at the two (thalamocortical versus intracortical) stages underlie differential selectivity for properties such as motion.
皮质回路是如何分析视觉场景的?在这里,我们探索纹状皮质处理的最早阶段:第一阶段,方向敏感性出现;第二阶段,刺激选择性进一步细化。研究方法是在猫活体上进行全细胞记录。丘脑外侧膝状体核中的神经元具有圆形感受野,其亚区域,即中心和周边是同心排列的,并且具有相反的信号,开或关。这些神经元为皮质简单细胞提供输入,皮质简单细胞的感受野具有并排排列的开和关亚区域。前馈模型认为,方向敏感性取决于感受野结构的这种丘脑皮质变化以及亚区域内的一种排列,即相反对比度的刺激会引发相反极性的突触反应——推挽式。我们的工作为前馈模型提供了支持,并强调推挽式是膝状体纹状通路的关键,由丘脑中继细胞从视网膜保留下来,并由皮质简单细胞逐点重复。此外,我们通过识别抑制性简单细胞来帮助定义皮质推挽回路。最后,比较皮质处理的第一和第二阶段的单独实验表明,两个阶段(丘脑皮质与皮质内)连接的突触生理学差异是对运动等特性的选择性差异的基础。