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一个注意力调制神经动力学的神经网络模型。

A neural network model of attention-modulated neurodynamics.

机构信息

Department of Biometry and Engineering, SLU, Uppsala, Sweden.

出版信息

Cogn Neurodyn. 2007 Dec;1(4):275-85. doi: 10.1007/s11571-007-9028-7. Epub 2007 Oct 2.

DOI:10.1007/s11571-007-9028-7
PMID:19003498
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2289046/
Abstract

Visual attention appears to modulate cortical neurodynamics and synchronization through various cholinergic mechanisms. In order to study these mechanisms, we have developed a neural network model of visual cortex area V4, based on psychophysical, anatomical and physiological data. With this model, we want to link selective visual information processing to neural circuits within V4, bottom-up sensory input pathways, top-down attention input pathways, and to cholinergic modulation from the prefrontal lobe. We investigate cellular and network mechanisms underlying some recent analytical results from visual attention experimental data. Our model can reproduce the experimental findings that attention to a stimulus causes increased gamma-frequency synchronization in the superficial layers. Computer simulations and STA power analysis also demonstrate different effects of the different cholinergic attention modulation action mechanisms.

摘要

视觉注意力似乎通过各种胆碱能机制调节皮层神经动力学和同步。为了研究这些机制,我们根据心理物理学、解剖学和生理学数据,开发了一个 V4 视皮层的神经网络模型。有了这个模型,我们希望将选择性视觉信息处理与 V4 内的神经回路、自下而上的感觉输入途径、自上而下的注意力输入途径以及来自前额叶的胆碱能调制联系起来。我们研究了一些最近的视觉注意力实验数据的分析结果所基于的细胞和网络机制。我们的模型可以再现实验结果,即注意力集中在刺激上会导致浅层的伽马频率同步增加。计算机模拟和 STA 功率分析也表明了不同的胆碱能注意力调制作用机制的不同影响。

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