Merchant H, Battaglia-Mayer A, Georgopoulos A P
Brain Sciences Center, Department of Veterans Affairs Medical Center, Minneapolis, MN 55417, USA.
J Neurophysiol. 2001 Oct;86(4):1937-54. doi: 10.1152/jn.2001.86.4.1937.
Moving visual stimuli were presented to behaving monkeys who fixated their eyes and did not move their arm. The stimuli consisted of random dots moving coherently in eight different kinds of motion (right, left, up, downward, expansion, contraction, clockwise, and counterclockwise) and were presented in 25 square patches on a liquid crystal display projection screen. Neuronal activity in the arm area of the motor cortex and area 7a was significantly influenced by the visual stimulation, as assessed using an ANOVA. The percentage of cells with a statistically significant effect of visual stimulation was 3 times greater in area 7a (370/587, 63%) than in motor cortex (148/693, 21.4%). With respect to stimulus properties, its location and kind of motion had differential effects on cell activity in the two areas. Specifically, the percentage of cells with a significant stimulus location effect was approximately 2.5 times higher in area 7a (311/370, 84%) than in motor cortex (48/148, 32.4%), whereas the percentage of cells with a significant stimulus motion effect was approximately 2 times higher in the motor cortex (79/148, 53.4%) than in area 7a (102/370, 27.6%). We also assessed the selectivity of responses to particular stimulus motions using a Poisson train analysis and determined the percentage of cells that showed activation in only one stimulus condition. This percentage was 2 times higher in the motor cortex (73.7%) than in area 7a (37.7%). Of all kinds of stimulus motion tested, responses to expanding optic flow were the strongest in both cortical areas. Finally, we compared the activation of motor cortical cells during visual stimulation to that observed during force exertion in a center --> out task. Of 514 cells analyzed for both the motor and visual tasks, 388 (75.5%) showed a significant relation to either or both tasks, as follows: 284/388 (73.2%) cells showed a significant relation only to the motor task, 27/388 (7%) cells showed a significant relation only to the visual task, whereas the remaining 77/388 (19.8%) cells showed significant relations to both tasks. Therefore a total of 361/514 (70.2%) cells were related to the motor task and 104/514 (20.2%) were related to the visual task. Finally, with respect to receptive fields (RFs), there was no clear visual receptive field structure in the motor cortical neuronal responses, in contrast to area 7a where RFs were present and could be modulated by the type of optic flow stimulus.
将移动的视觉刺激呈现给注视眼睛且不移动手臂的行为猴子。刺激由在八种不同运动(右、左、上、下、扩张、收缩、顺时针和逆时针)中连贯移动的随机点组成,并呈现在液晶显示投影屏幕上的25个方形斑块中。使用方差分析评估发现,运动皮层手臂区域和7a区的神经元活动受到视觉刺激的显著影响。在7a区,受视觉刺激有统计学显著效应的细胞百分比(370/587,63%)比运动皮层(148/693,21.4%)高3倍。就刺激特性而言,其位置和运动类型对这两个区域的细胞活动有不同影响。具体而言,7a区中受刺激位置有显著效应的细胞百分比(311/370,84%)比运动皮层(48/148,32.4%)高约2.5倍,而运动皮层中受刺激运动有显著效应的细胞百分比(79/148,53.4%)比7a区(102/370,27.6%)高约2倍。我们还使用泊松序列分析评估了对特定刺激运动反应的选择性,并确定了仅在一种刺激条件下显示激活的细胞百分比。该百分比在运动皮层(73.7%)比7a区(37.7%)高2倍。在所有测试的刺激运动类型中,对扩张性光流的反应在两个皮层区域中最强。最后,我们将视觉刺激期间运动皮层细胞的激活与在中心→外周任务中用力时观察到的激活进行了比较。在对运动和视觉任务都进行分析 的514个细胞中,388个(75.5%)与其中一项或两项任务有显著关系,具体如下:284/388(73.2%)个细胞仅与运动任务有显著关系,27/388(7%)个细胞仅与视觉任务有显著关系,而其余77/388(19.8%)个细胞与两项任务都有显著关系。因此,共有361/514(70.2%)个细胞与运动任务相关,104/514(20.2%)个细胞与视觉任务相关。最后,关于感受野(RFs),运动皮层神经元反应中没有清晰的视觉感受野结构,这与7a区不同,在7a区存在感受野且可由光流刺激类型调节。
