A synaptic learning rule for exploiting nonlinear dendritic computation

Bicknell Brendan A.; Hausser Michael

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A synaptic learning rule for exploiting nonlinear dendritic computation

机译：A synaptic learning rule for exploiting nonlinear dendritic computation

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摘要

Information processing in the brain depends on the integration of synaptic input distributed throughout neuronal dendrites. Dendritic integration is a hierarchical process, proposed to be equivalent to integration by a multilayer network, potentially endowing single neurons with substantial computational power. However, whether neurons can learn to harness dendritic properties to realize this potential is unknown. Here, we develop a learning rule from dendritic cable theory and use it to investigate the processing capacity of a detailed pyramidal neuron model. We show that computations using spatial or temporal features of synaptic input patterns can be learned, and even synergistically combined, to solve a canonical nonlinear feature-binding problem. The voltage dependence of the learning rule drives coactive synapses to engage dendritic nonlinearities, whereas spike-timing dependence shapes the time course of subthreshold potentials. Dendritic input-output relationships can therefore be flexibly tuned through synaptic plasticity, allowing optimal implementation of nonlinear functions by single neurons.

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《Neuron》 |2021年第24期|4001-4017|共17页
作者
Bicknell Brendan A.; Hausser Michael;
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作者单位

Wolfson Inst Biomed Res,UCL;

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原文格式 PDF
正文语种英语
中图分类神经病学;
关键词
PYRAMIDAL NEURON; ACTION-POTENTIALS; BASAL DENDRITES; NMDA SPIKES; INFORMATION-STORAGE; THIN DENDRITES; MODEL; INTEGRATION; PLASTICITY; PROPAGATION;

A synaptic learning rule for exploiting nonlinear dendritic computation

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