Weight dependence in BCM leads to adjustable synaptic competition.

IF 1.5 4区医学 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Journal of Computational Neuroscience Pub Date : 2022-11-01 DOI:10.1007/s10827-022-00824-w

Albert Albesa-González, Maxime Froc, Oliver Williamson, Mark C W van Rossum

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引用次数: 2

Abstract

Models of synaptic plasticity have been used to better understand neural development as well as learning and memory. One prominent classic model is the Bienenstock-Cooper-Munro (BCM) model that has been particularly successful in explaining plasticity of the visual cortex. Here, in an effort to include more biophysical detail in the BCM model, we incorporate 1) feedforward inhibition, and 2) the experimental observation that large synapses are relatively harder to potentiate than weak ones, while synaptic depression is proportional to the synaptic strength. These modifications change the outcome of unsupervised plasticity under the BCM model. The amount of feed-forward inhibition adds a parameter to BCM that turns out to determine the strength of competition. In the limit of strong inhibition the learning outcome is identical to standard BCM and the neuron becomes selective to one stimulus only (winner-take-all). For smaller values of inhibition, competition is weaker and the receptive fields are less selective. However, both BCM variants can yield realistic receptive fields.

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BCM的体重依赖性导致可调节的突触竞争。

突触可塑性模型已经被用来更好地理解神经发育以及学习和记忆。一个突出的经典模型是Bienenstock-Cooper-Munro (BCM)模型，它在解释视觉皮层的可塑性方面特别成功。在这里，为了在BCM模型中包含更多的生物物理细节，我们结合了1)前馈抑制，以及2)实验观察到的大突触比弱突触相对更难增强，而突触抑制与突触强度成正比。这些修正改变了BCM模型下的无监督塑性结果。前馈抑制的数量为BCM增加了一个参数，最终决定了竞争的强度。在强抑制的极限下，学习结果与标准BCM相同，神经元只选择一个刺激(赢者通吃)。抑制值越小，竞争越弱，接受野的选择性越差。然而，这两种BCM变体都可以产生现实的接受域。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Computational Neuroscience 生物-神经科学

CiteScore

2.00

自引率

8.30%

发文量

审稿时长

3 months

期刊介绍： The Journal of Computational Neuroscience provides a forum for papers that fit the interface between computational and experimental work in the neurosciences. The Journal of Computational Neuroscience publishes full length original papers, rapid communications and review articles describing theoretical and experimental work relevant to computations in the brain and nervous system. Papers that combine theoretical and experimental work are especially encouraged. Primarily theoretical papers should deal with issues of obvious relevance to biological nervous systems. Experimental papers should have implications for the computational function of the nervous system, and may report results using any of a variety of approaches including anatomy, electrophysiology, biophysics, imaging, and molecular biology. Papers investigating the physiological mechanisms underlying pathologies of the nervous system, or papers that report novel technologies of interest to researchers in computational neuroscience, including advances in neural data analysis methods yielding insights into the function of the nervous system, are also welcomed (in this case, methodological papers should include an application of the new method, exemplifying the insights that it yields).It is anticipated that all levels of analysis from cognitive to cellular will be represented in the Journal of Computational Neuroscience.