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开发一个非平稳计算框架及其在神经尖峰响应动态调制建模中的应用。

Developing a Nonstationary Computational Framework With Application to Modeling Dynamic Modulations in Neural Spiking Responses.

出版信息

IEEE Trans Biomed Eng. 2018 Feb;65(2):241-253. doi: 10.1109/TBME.2017.2762687. Epub 2017 Oct 13.

DOI:10.1109/TBME.2017.2762687
PMID:29035203
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5796416/
Abstract

OBJECTIVE

This paper aims to develop a computational model that incorporates the functional effects of modulatory covariates (such as context, task, or behavior), which dynamically alter the relationship between the stimulus and the neural response.

METHODS

We develop a general computational approach along with an efficient estimation procedure in the widely used generalized linear model (GLM) framework to characterize such nonstationary dynamics in spiking response and spatiotemporal characteristics of a neuron at the level of individual trials. The model employs a set of modulatory components, which nonlinearly interact with other stimulus-related signals to reproduce such nonstationary effects.

RESULTS

The model is tested for its ability to predict the responses of neurons in the middle temporal cortex of macaque monkeys during an eye movement task. The fitted model proves successful in capturing the fast temporal modulations in the response, reproducing the spike response temporal statistics, and accurately accounting for the neurons' dynamic spatiotemporal sensitivities, during eye movements.

CONCLUSION

The nonstationary GLM framework developed in this study can be used in cases where a time-varying behavioral or cognitive component makes GLM-based models insufficient to describe the dependencies of neural responses on the stimulus-related covariates.

SIGNIFICANCE

In addition to being quite powerful in encoding time-varying response modulations, this general framework also enables a readout of the neural code while dissociating the influence of other nonstimulus covariates. This framework will advance our ability to understand sensory processing in higher brain areas when modulated by several behavioral or cognitive variables.

摘要

目的

本文旨在开发一种计算模型,该模型将整合调节协变量(如上下文、任务或行为)的功能效应,这些协变量会动态改变刺激与神经反应之间的关系。

方法

我们在广泛使用的广义线性模型(GLM)框架中开发了一种通用的计算方法和一种有效的估计程序,以在个体试验水平上描述尖峰反应和神经元时空特征中的这种非平稳动力学。该模型采用了一组调节组件,这些组件与其他与刺激相关的信号非线性相互作用,以再现这种非平稳效应。

结果

该模型经过测试,用于预测猕猴中颞叶中部神经元在眼球运动任务期间的反应。拟合模型成功地捕获了反应中的快速时间调制,再现了尖峰反应的时间统计,并准确地解释了神经元在眼球运动过程中的动态时空敏感性。

结论

本研究中开发的非平稳 GLM 框架可用于以下情况:时变行为或认知成分使得基于 GLM 的模型不足以描述神经反应对与刺激相关的协变量的依赖性。

意义

除了在编码时变反应调制方面非常强大之外,这个通用框架还能够在分离其他非刺激协变量的影响的同时读取神经代码。该框架将提高我们理解多个行为或认知变量调制时大脑高级区域感觉处理的能力。

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本文引用的文献

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Mechanisms of Saccadic Suppression in Primate Cortical Area V4.灵长类动物视皮层V4区扫视抑制的机制
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