上丘内源性输入的动机调节

Proceedings. 2005 IEEE International Joint Conference on Neural Networks, 2005. Pub Date : 2005-12-27 DOI:10.1109/IJCNN.2005.1555840

J. Satel, T. Trappenberg, R. Klein

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引用次数: 3

摘要

跳眼运动的正常启动取决于外源性和内源性控制机制之间的复杂平衡。上丘(SC)是信号整合的主要部位，已被证明可以驱动脑干中扫视的启动。先前的研究表明，用连续吸引子神经网络(CANN)实现的赢者通吃机制可以解释和重现许多行为发现，包括K. Kopecz(1995)和T.P. trappberg(2001)的间隙效应和表达扫视的产生。这项研究在几个重要的方面推进了跳眼起始的CANN模型，以便以生物学上合理的方式解释跳眼反应时间的一次又一次适应。一个关键的假设是，SC中间层的内源性输入可以通过来自大脑其他区域(如基底神经节或高级皮质区域)的基于动机的反馈来适应。

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Motivational modulation of endogenous inputs to the superior colliculus

Proper initiation of saccadic eye movements depends on an intricate balance between exogenous and endogenous control mechanisms. The superior colliculus (SC) is a major site of signal integration that has been shown to drive the initiation of saccades in the brainstem. Previous work has shown that a winner-take-all mechanism implemented with a continuous attractor neural network (CANN) can explain and reproduce a multitude of behavioural findings, including the gap effect and the production of express saccades by K. Kopecz (1995) and by T.P. Trappenberg (2001). This investigation advances the CANN model of saccade initiation in several important ways in order to account for trial by trial adaptation of saccadic reaction times in a biologically plausible manner. A key hypothesis is that endogenous inputs to the intermediate layer of the SC can be adapted through motivationally-based feedback from other areas of the brain such as the basal ganglia or higher cortical areas.

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Proceedings. 2005 IEEE International Joint Conference on Neural Networks, 2005.

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