Lauwereyns J, Sakagami M, Tsutsui K, Kobayashi S, Koizumi M, Hikosaka O
Department of Physiology, Juntendo University, Tokyo 113-0033, Japan.
J Neurophysiol. 2001 Oct;86(4):2001-10. doi: 10.1152/jn.2001.86.4.2001.
The primate brain is equipped with prefrontal circuits for interpreting visual information, but how these circuits deal with competing stimulus-response (S-R) associations remains unknown. Here we show different types of responses to task-irrelevant visual features in three functionally dissociated groups of primate prefrontal neurons. Two Japanese macaques participated in a go/no-go task in which they had to discriminate either the color or the motion direction of a visual target to make a correct manual response. Prior to the experiment, the monkeys had been trained extensively so that they acquired fixed associations between visual features and required responses (e.g., "green = go"; "downward motion = no-go"). In this design, the monkey was confronted with a visual target from which it had to extract relevant information (e.g., color in the color-discrimination condition) while ignoring irrelevant information (e.g., motion direction in the color-discrimination condition). We recorded from 436 task-related prefrontal neurons while the monkey performed the multidimensional go/no-go task: 139 (32%) neurons showed go/no-go discrimination based on color as well as motion direction ("integration cells"); 192 neurons (44%) showed go/no-go discrimination only based on color ("color-feature cells"); and 105 neurons (24%) showed go/no-go discrimination only based on motion direction ("motion-feature cells"). Overall, however, 162 neurons (37%) were influenced by irrelevant information: 53 neurons (38%) among integration cells, 71 neurons (37%) among color-feature cells, and 38 neurons (36%) among motion-feature cells. Across all types of neurons, the response to an irrelevant feature was positively correlated with the response to the same feature when it was relevant, indicating that the influence from irrelevant information is a residual from S-R associations that are relevant in a different context. Temporal and anatomical differences among integration, color-feature and motion-feature cells suggested a sequential mode of information processing in prefrontal cortex, with integration cells situated toward the output of the decision-making process. In these cells, the response to irrelevant information appears as a congruency effect, with better go/no-go discrimination when both the relevant and irrelevant feature are associated with the same response than when they are associated with different responses. This congruency effect could be the result of the combined input from color- and motion-feature cells. Thus these data suggest that irrelevant features lead to partial activation of neurons even toward the output of the decision-making process in primate prefrontal cortex.
灵长类动物的大脑配备了用于解释视觉信息的前额叶回路,但这些回路如何处理相互竞争的刺激-反应(S-R)关联仍不清楚。在这里,我们展示了灵长类动物前额叶神经元的三个功能不同的组对与任务无关的视觉特征的不同类型反应。两只日本猕猴参与了一个“是/否”任务,在该任务中,它们必须辨别视觉目标的颜色或运动方向才能做出正确的手动反应。在实验之前,猴子已经接受了广泛的训练,以便它们在视觉特征和所需反应之间建立固定的关联(例如,“绿色=是”;“向下运动=否”)。在这种设计中,猴子面对一个视觉目标,它必须从中提取相关信息(例如,在颜色辨别条件下的颜色),同时忽略无关信息(例如,在颜色辨别条件下的运动方向)。当猴子执行多维“是/否”任务时,我们记录了436个与任务相关的前额叶神经元:139个(32%)神经元基于颜色以及运动方向进行“是/否”辨别(“整合细胞”);192个神经元(44%)仅基于颜色进行“是/否”辨别(“颜色特征细胞”);105个神经元(24%)仅基于运动方向进行“是/否”辨别(“运动特征细胞”)。然而,总体而言,162个神经元(37%)受到无关信息的影响:整合细胞中有53个神经元(38%),颜色特征细胞中有71个神经元(37%),运动特征细胞中有38个神经元(36%)。在所有类型的神经元中,对无关特征的反应与该特征相关时的反应呈正相关,这表明来自无关信息的影响是在不同背景下相关的S-R关联的残余。整合细胞、颜色特征细胞和运动特征细胞之间的时间和解剖学差异表明前额叶皮层存在信息处理的顺序模式,整合细胞位于决策过程的输出端。在这些细胞中,对无关信息的反应表现为一致性效应,当相关和无关特征都与相同反应相关联时,“是/否”辨别比它们与不同反应相关联时更好。这种一致性效应可能是颜色和运动特征细胞联合输入的结果。因此这些数据表明,即使在灵长类动物前额叶皮层决策过程的输出端,无关特征也会导致神经元的部分激活。
