Wang C, Dreher B
Department of Anatomy and Histology (F13), University of Sydney, N.S.W., Australia.
Exp Brain Res. 1996 Mar;108(2):257-72. doi: 10.1007/BF00228099.
We have examined, using both qualitative and quantitative techniques, binocular interactions of extracellularly recorded single neurons in the extrastriate cortical area 21a of anaesthetized and paralysed cats. Consistent with previous reports we have found that: (a) all area 21a neurons were orientation-selective, with about 65% of them preferring orientations within 30 degrees of the vertical; and (b) over 75% of area 21a cells could be activated through either eye. Furthermore, a significant minority (4 cells; about 10%) of a subpopulation of 39 neurons in which binocular interactions were examined quantitatively, were "obligatory binocular neurons", that is, they responded very weakly, if at all, to the monocular stimuli presented through either eye but responded vigorously to simultaneous stimulation through both eyes. Almost 70% (27/39) of neurons tested quantitatively for binocular interaction have shown significant modulation (over 50%) of their peak responses in relation to binocular positional retinal disparities. The majority of neurons sensitive to binocular positional disparities resembled either "tuned excitatory" (22 cells; 56.5% of the sample) or "tuned inhibitory" (2 cells; 5% of our sample) cells. In particular, they gave, respectively, maximal or minimal responses to optimally oriented, moving photic stimuli when the receptive fields plotted through each eye completely or partially overlapped. Although neurons recorded in area 21a have relatively large receptive fields (mean width 3.3 +/- 1.1 degrees; range 2.0-5.6 degrees), the mean width of the disparity tuning curve (2.8 +/- 1.0 degrees; range 1.3-4.8 degrees) for our sample of area 21a neurons was similar to those of neurons with significantly smaller receptive fields, recorded in areas 17 and 18 of cat's primary visual cortex. We conclude that area 21a of the cat, like areas 17 and 18 of primary visual cortex, is likely to play an important role in binocular depth discrimination and might constitute a "higher order" area for stereoscopic binocular vision.
我们运用定性和定量技术,对麻醉并瘫痪的猫的纹外皮质21a区细胞外记录的单个神经元的双眼相互作用进行了研究。与之前的报告一致,我们发现:(a) 所有21a区神经元都具有方向选择性,其中约65%的神经元偏好垂直方向30度以内的方向;(b) 超过75%的21a区细胞可通过任一只眼睛激活。此外,在定量研究双眼相互作用的39个神经元亚群中,有一小部分(4个细胞;约10%)是“强制性双眼神经元”,即它们对通过任一只眼睛呈现的单眼刺激反应非常微弱(如果有反应的话),但对双眼同时刺激反应强烈。在定量测试双眼相互作用的神经元中,近70%(27/39)的神经元峰值反应相对于双眼视网膜位置差异有显著调制(超过50%)。大多数对双眼位置差异敏感的神经元类似于“调谐兴奋性”细胞(22个细胞;样本的56.5%)或“调谐抑制性”细胞(2个细胞;样本的5%)。具体而言,当通过每只眼睛绘制的感受野完全或部分重叠时,它们分别对最佳方向的移动光刺激给出最大或最小反应。尽管在21a区记录的神经元具有相对较大的感受野(平均宽度3.3±1.1度;范围2.0 - 5.6度),但我们的21a区神经元样本的差异调谐曲线平均宽度(2.8±1.0度;范围1.
