Yamane S, Maske R, Bishop P O
Exp Brain Res. 1985;57(3):523-36. doi: 10.1007/BF00237839.
The response properties of 84 simple striate cells in anaesthetized (N2O/O2 supplemented with sodium pentobarbital) and paralyzed cats were examined quantitatively using narrow optimally-oriented light and dark bars moving at optimal velocities. Different cells gave two to five spatially-offset response peaks, the light bar and the dark bar response peaks alternating with one another. With only 5 exceptions, the cells had the same preferred direction for movement of the dark bar as for the light bar. Static-field plots were prepared from 32 of the 84 cells using stationary flashing bars. The receptive fields of different cells had from two to four subregions responding either at light on (ON subregion) or at light off (OFF subregion) although one cell had only a single subregion. In the preferred direction of stimulus movement cells gave either the same number of response peaks to moving bars as there were subregions or one additional response peak. The additional response peak, termed a boundary response, always occurred at the end of the sequence of response peaks and was always completely direction selective. The direction selectivities of the individual response peaks in the responses from 49 of the 84 cells were analyzed. To ensure that each response peak and the corresponding peak in the opposite direction both came from the same subregion, the 49 cells were selected on the basis of having a response in the nonpreferred direction sufficient for analysis and of having a stimulus velocity less than 2.5 degrees/s so as to avoid significant spatial shifts of the peaks due to response latencies. For all but two of the 49 cells, the response peaks in any given profile always showed a progressively greater degree of direction selectivity as the stimulus advanced from one subregion to the next, the first subregion giving the least directionally-selective response peak and the last subregion the most directionally-selective peak. This observation was independent of the direction of stimulus motion and of the particular sequence in which the ON and the OFF subregions were traversed by the stimulus. The response patterns observed experimentally have been correlated with theoretical response patterns based on the responses of lateral geniculate neurons.
在麻醉(补充有戊巴比妥钠的N₂O/O₂)且瘫痪的猫中,使用以最佳速度移动的狭窄的最佳取向的亮条和暗条,对84个简单视皮层细胞的反应特性进行了定量研究。不同的细胞给出了两到五个空间偏移的反应峰值,亮条和暗条的反应峰值相互交替。除了5个例外,细胞对暗条和亮条的运动具有相同的偏好方向。使用静止的闪烁条为84个细胞中的32个绘制了静态场图。不同细胞的感受野有两到四个子区域,在光开启(ON子区域)或光关闭(OFF子区域)时做出反应,尽管有一个细胞只有一个子区域。在刺激运动的偏好方向上,细胞对移动条给出的反应峰值数量与子区域数量相同,或者多一个反应峰值。这个额外的反应峰值,称为边界反应,总是出现在反应峰值序列的末尾,并且总是完全具有方向选择性。分析了84个细胞中49个细胞反应中各个反应峰值的方向选择性。为确保每个反应峰值和相反方向的相应峰值都来自同一个子区域,选择了49个细胞,其依据是在非偏好方向上有足够用于分析的反应,并且刺激速度小于2.5度/秒,以避免由于反应潜伏期导致峰值出现显著的空间偏移。对于49个细胞中除了两个之外的所有细胞,在任何给定的剖面图中,随着刺激从一个子区域推进到下一个子区域,反应峰值总是显示出逐渐增强的方向选择性程度,第一个子区域给出的方向选择性反应峰值最小,最后一个子区域给出的方向选择性峰值最大。这一观察结果与刺激运动方向以及刺激穿过ON和OFF子区域的特定顺序无关。实验观察到的反应模式已与基于外侧膝状体神经元反应的理论反应模式相关联。
