Lurito J T, Georgakopoulos T, Georgopoulos A P
Philip Bard Laboratories of Neurophysiology, Department of Neuroscience, Johns Hopkins University School of Medicine, Baltimore, MD 21205.
Exp Brain Res. 1991;87(3):562-80. doi: 10.1007/BF00227082.
Two rhesus monkeys were trained to move a handle on a two-dimensional (2-D) working surface either towards a visual stimulus ("direct" task) or in a direction orthogonal and counterclockwise (CCW) from the stimulus ("transformation" task), depending on whether the stimulus appeared dim or bright, respectively. Thus the direction of the stimulus (S, in polar coordinates) and the direction of the movement (M) were the same in the direct task but differed in the transformation task, such that M = S + 90 degrees CCW. The task (i.e. brightness) condition (k = 2, i.e. direct or transformation) and the direction of the stimulus (m = 8, i.e. 8 equally spaced directions on a circle) resulted in 16 combinations (k x m = 16 "classes") that were varied from trial to trial in a randomized block design. In 8 of these combinations the direction of the stimulus was the same for both tasks, whereas the direction of the movement was the same in the remaining 8 cases. The electrical signs of cell activity (N = 394 cells) in the arm area of the motor cortex (contralateral to the performing arm) were recorded extracellularly. The neural activity was analyzed at the single cell and neuronal population levels, and a modeling of the time course of single activity during the transformation task was carried out. We found the following. (a) Individual cells were active in both tasks; no cells were found that were active exclusively in only one of the two tasks. The patterns of single cell activity in the transformation task frequently differed from those observed in the direct task when the stimulus or the movement were the same. More specifically, cells could not be consistently classified as "movement"-or "stimulus"-related for frequently the activity of a particular cell would seem "movement-related" for a particular stimulus-movement combination, "stimulus-related" for another combination, or unrelated to either movement or stimulus for still another combination. Thus no real insight could be gained from such an analysis of single cell activity. (e) In a different analysis, we explored the idea that a changing directional signal could be detected in the time course of single cell activity during the reaction time. For that purpose we modeled the time course of single activity observed in the transformation task as a linear, weighted combination of influences from the direct task, taking the time patterns of cell activity during the stimulus, intermediate and movement directions in the direct task as estimates of the postulated directional influences.(ABSTRACT TRUNCATED AT 400 WORDS)
训练了两只恒河猴,让它们根据视觉刺激是暗还是亮,在二维工作表面上把操纵杆朝着视觉刺激方向移动(“直接”任务),或者朝着与刺激方向正交且逆时针方向(“转换”任务)移动。因此,在直接任务中,刺激方向(S,极坐标表示)和移动方向(M)相同,但在转换任务中不同,即M = S + 90度逆时针。任务(即亮度)条件(k = 2,即直接或转换)和刺激方向(m = 8,即在圆上8个等间隔方向)产生16种组合(k×m = 16“类别”),在随机区组设计中每次试验都进行变化。在这些组合中的8种中,两种任务的刺激方向相同,而在其余8种情况下移动方向相同。在运动皮层的手臂区域(与执行手臂对侧)细胞活动(N = 394个细胞)的电信号进行了细胞外记录。在单细胞和神经元群体水平上分析神经活动,并对转换任务期间单个活动的时间进程进行建模。我们发现如下情况。(a)单个细胞在两个任务中都有活动;没有发现仅在两个任务之一中活跃的细胞。当刺激或移动相同时,转换任务中单个细胞活动的模式经常与直接任务中观察到的不同。更具体地说,细胞不能一致地归类为“与移动相关”或“与刺激相关”,因为对于特定的刺激 - 移动组合,特定细胞的活动可能看起来“与移动相关”,对于另一种组合则“与刺激相关”,或者对于另一种组合与移动或刺激都无关。因此,从这种单细胞活动分析中无法获得真正的见解。(e)在另一种分析中,我们探讨了在反应时间内单细胞活动的时间进程中可以检测到变化的方向信号的想法。为此,我们将转换任务中观察到的单个活动的时间进程建模为直接任务影响的线性加权组合,将直接任务中刺激、中间和移动方向期间的细胞活动时间模式作为假定方向影响的估计值。(摘要截断于400字)
