Modulation of Dopamine for Adaptive Learning: A Neurocomputational Model.

Computational brain & behavior Pub Date : 2021-03-01 Epub Date: 2020-06-12 DOI:10.1007/s42113-020-00083-x

Jeffrey B Inglis, Vivian V Valentin, F Gregory Ashby

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引用次数: 1

Abstract

There have been many proposals that learning rates in the brain are adaptive, in the sense that they increase or decrease depending on environmental conditions. The majority of these models are abstract and make no attempt to describe the neural circuitry that implements the proposed computations. This article describes a biologically detailed computational model that overcomes this shortcoming. Specifically, we propose a neural circuit that implements adaptive learning rates by modulating the gain on the dopamine response to reward prediction errors, and we model activity within this circuit at the level of spiking neurons. The model generates a dopamine signal that depends on the size of the tonically active dopamine neuron population and the phasic spike rate. The model was tested successfully against results from two single-neuron recording studies and a fast-scan cyclic voltammetry study. We conclude by discussing the general applicability of the model to dopamine mediated tasks that transcend the experimental phenomena it was initially designed to address.

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多巴胺对适应性学习的调节:一个神经计算模型。

有很多人认为大脑的学习率是适应性的，也就是说，大脑的学习率会随着环境条件的变化而增加或减少。这些模型大多是抽象的，并没有试图描述实现所提出的计算的神经回路。本文描述了一个生物学上详细的计算模型，克服了这一缺点。具体来说，我们提出了一个神经回路，通过调节多巴胺对奖励预测错误的反应增益来实现自适应学习率，我们在尖峰神经元的水平上模拟了该回路中的活动。该模型产生的多巴胺信号取决于张力活跃的多巴胺神经元数量的大小和相尖峰率。该模型与两个单神经元记录研究和快速扫描循环伏安法研究的结果进行了成功的测试。最后，我们讨论了该模型对多巴胺介导的任务的一般适用性，这些任务超越了它最初设计用于解决的实验现象。

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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