From both functional and biological considerations, it is widely believed that action production, planning, and goal-oriented behaviors supported by the frontal cortex are organized hierarchically [Fuster (1991); Koechlin, E., Ody, C., & Kouneiher, F. (2003). Neuroscience: The architecture of cognitive control in the human prefrontal cortex. Science, 424, 1181-1184; Miller, G. A., Galanter, E., & Pribram, K. H. (1960). Plans and the structure of behavior. New York: Holt]. However, the nature of the different levels of the hierarchy remains unclear, and little attention has been paid to the origins of such a hierarchy. We address these issues through biologically-inspired computational models that develop representations through reinforcement learning. We explore several different factors in these models that might plausibly give rise to a hierarchical organization of representations within the PFC, including an initial connectivity hierarchy within PFC, a hierarchical set of connections between PFC and subcortical structures controlling it, and differential synaptic plasticity schedules. Simulation results indicate that architectural constraints contribute to the segregation of different types of representations, and that this segregation facilitates learning. These findings are consistent with the idea that there is a functional hierarchy in PFC, as captured in our earlier computational models of PFC function and a growing body of empirical data.
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机译:从功能和生物学的角度出发,人们普遍认为额叶皮层支持的动作的产生,计划和目标导向的行为是分层组织的[Fuster(1991); Koechlin,E.,Ody,C。,&Kouneiher,F。(2003)。神经科学:人类额叶皮层认知控制的体系结构。科学424,1181-1184; Miller G.A.,Galanter E.和Pribram K.H.(1960)。计划和行为结构。纽约:霍尔特]。但是,层次结构的不同级别的性质仍不清楚,并且很少关注这种层次结构的起源。我们通过受生物启发的计算模型来解决这些问题,该模型通过强化学习来发展表示形式。我们探索了这些模型中的几个不同因素,这些因素可能会引起PFC内表示的层次化组织,包括PFC内的初始连接层次结构,PFC和控制它的皮层下结构之间的连接层次结构集以及不同的突触可塑性计划。仿真结果表明,体系结构约束有助于分离不同类型的表示形式,并且这种分离有助于学习。这些发现与我们先前的PFC函数计算模型和越来越多的经验数据所反映的PFC中存在功能层次的想法是一致的。
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