顶叶皮质中乘法神经反应的模型。
A model of multiplicative neural responses in parietal cortex.
作者信息
Salinas E, Abbott L F
机构信息
Volen Center for Complex Systems, Brandeis University, Waltham, MA 02254-9110, USA.
出版信息
Proc Natl Acad Sci U S A. 1996 Oct 15;93(21):11956-61. doi: 10.1073/pnas.93.21.11956.
Abstract
Visual responses of neurons in parietal area 7a are modulated by a combined eye and head position signal in a multiplicative manner. Neurons with multiplicative responses can act as powerful computational elements in neural networks. In the case of parietal cortex, multiplicative gain modulation appears to play a crucial role in the transformation of object locations from retinal to body-centered coordinates. It has proven difficult to uncover single-neuron mechanisms that account for neuronal multiplication. Here we show that multiplicative responses can arise in a network model through population effects. Specifically, neurons in a recurrently connected network with excitatory connections between similarly tuned neurons and inhibitory connections between differently tuned neurons can perform a product operation on additive synaptic inputs. The results suggest that parietal responses may be based on this architecture.
摘要
顶叶7a区神经元的视觉反应通过眼睛和头部位置的组合信号以乘法方式进行调制。具有乘法反应的神经元可作为神经网络中强大的计算元件。就顶叶皮层而言,乘法增益调制似乎在将物体位置从视网膜坐标转换为以身体为中心的坐标过程中起着关键作用。事实证明,要揭示解释神经元乘法的单神经元机制很困难。在这里,我们表明乘法反应可以通过群体效应在网络模型中产生。具体来说,在一个循环连接的网络中,具有相似调谐神经元之间的兴奋性连接和不同调谐神经元之间的抑制性连接的神经元,可以对相加的突触输入执行乘积运算。结果表明,顶叶反应可能基于这种结构。
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