利用递归神经网络建立行为相关神经动态的分离和优先模型

IF 21.2 1区 医学 Q1 NEUROSCIENCES
Omid G. Sani, Bijan Pesaran, Maryam M. Shanechi
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引用次数: 0

摘要

要了解神经活动向行为的动态转化,就必须具备新的能力,对与行为相关的神经动态进行非线性建模、解离和优先排序,并测试有关非线性起源的假设。我们介绍了一种非线性动力学建模方法--动力学优先分解分析(DPAD),它通过多节神经网络架构和训练方法实现了这些功能。通过分析四种运动任务中的皮层尖峰和局部场电位活动,我们展示了五个使用案例。DPAD 能够进行更准确的神经行为预测。它能识别局部场电位的非线性动态变换,比传统的功率特征更能预测行为。此外,DPAD 还实现了行为预测性非线性神经降维。它能够对神经-行为转换中的非线性进行假设检验,揭示出在我们的数据集中,非线性在很大程度上可以被隔离到从潜在皮层动力学到行为的映射中。最后,DPAD 可以扩展到连续、间歇采样和分类行为。DPAD 为神经行为数据的非线性动力学建模和研究提供了强大的工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Dissociative and prioritized modeling of behaviorally relevant neural dynamics using recurrent neural networks

Dissociative and prioritized modeling of behaviorally relevant neural dynamics using recurrent neural networks

Dissociative and prioritized modeling of behaviorally relevant neural dynamics using recurrent neural networks
Understanding the dynamical transformation of neural activity to behavior requires new capabilities to nonlinearly model, dissociate and prioritize behaviorally relevant neural dynamics and test hypotheses about the origin of nonlinearity. We present dissociative prioritized analysis of dynamics (DPAD), a nonlinear dynamical modeling approach that enables these capabilities with a multisection neural network architecture and training approach. Analyzing cortical spiking and local field potential activity across four movement tasks, we demonstrate five use-cases. DPAD enabled more accurate neural–behavioral prediction. It identified nonlinear dynamical transformations of local field potentials that were more behavior predictive than traditional power features. Further, DPAD achieved behavior-predictive nonlinear neural dimensionality reduction. It enabled hypothesis testing regarding nonlinearities in neural–behavioral transformation, revealing that, in our datasets, nonlinearities could largely be isolated to the mapping from latent cortical dynamics to behavior. Finally, DPAD extended across continuous, intermittently sampled and categorical behaviors. DPAD provides a powerful tool for nonlinear dynamical modeling and investigation of neural–behavioral data. The authors present DPAD, a deep learning method, for dynamical neural–behavioral modeling. It dissociates behaviorally relevant neural dynamics, better predicts neural–behavioral data and reveals insight into where their nonlinearities can be isolated.
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来源期刊
Nature neuroscience
Nature neuroscience 医学-神经科学
CiteScore
38.60
自引率
1.20%
发文量
212
审稿时长
1 months
期刊介绍: Nature Neuroscience, a multidisciplinary journal, publishes papers of the utmost quality and significance across all realms of neuroscience. The editors welcome contributions spanning molecular, cellular, systems, and cognitive neuroscience, along with psychophysics, computational modeling, and nervous system disorders. While no area is off-limits, studies offering fundamental insights into nervous system function receive priority. The journal offers high visibility to both readers and authors, fostering interdisciplinary communication and accessibility to a broad audience. It maintains high standards of copy editing and production, rigorous peer review, rapid publication, and operates independently from academic societies and other vested interests. In addition to primary research, Nature Neuroscience features news and views, reviews, editorials, commentaries, perspectives, book reviews, and correspondence, aiming to serve as the voice of the global neuroscience community.
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