认知神经科学中蕴藏的力学思想与应用

王如彬; 王毅泓; 徐旭颖; 潘晓川

doi:10.6052/1000-0992-20-008

认知神经科学中蕴藏的力学思想与应用

doi: 10.6052/1000-0992-20-008 cstr: 32046.14.1000-0992-20-008

王如彬^1,2,†, ,,
王毅泓¹,
徐旭颖¹,
潘晓川¹

¹ 华东理工大学认知神经动力学研究所, 上海 200237
² 杭州电子科技大学计算机学院, 杭州 310018

基金项目:

国家自然科学基金资助项目 (11232005, 10872068, 11472104, 11872180).

详细信息

作者简介:
王如彬, 1998年毕业于日本名古屋大学, 获工学博士学位. 历任东华大学和华东理工大学教授、博士生导师, 华东理工大学认知神经动力学研究所所长. 曾任日本大阪大学名誉教授和日本玉川大学脑科学研究所研究教授, 多次访问日本理化学研究所. 1998年和2012年二次被日本学术振兴会(JSPS) 聘为外国人特别研究员, 国际脑联盟会员(DANA Alliance for Brain Initiatives (DABI). 现为杭州电子科技大学讲座教授, 主要从事认知神经动力学与脑信息处理等交叉学科研究. 已在国内外发表科研论文200多篇, 其中SCI收录论文160多篇. 主持和正在主持8项国家自然科学基金, 包括1项国家自然科学基金重点项目和5个面上项目. SCI源刊Cognitive Neurodynamics的主编. 第一届(2007)、第二届(2009)和第五届(2015) The International Conference on Cognitive Neurodynamics (ICCN)的主席. 第一届(2012年)、第三届(2016年)、第四届(2018年)和第五届(2020) 全国神经动力学会议主席. 第一届(2017年)和第二届(2019年) 认知神经科学与智能应用杭州国际研讨会主席.

通讯作者:
王如彬

中图分类号: Q66
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出版历程
- 收稿日期: 2020-04-17
- 刊出日期: 2020-10-08

Mechanical thoughts and applications in cognitive neuroscience

WANG Rubin^{1,2,†
, ,},
WANG Yihong¹,
XU Xuying¹,
PAN Xiaochuan¹

¹ Institute for Cognitive Neurodynamics, East China University of Science and Technology, Shanghai 200237, China
² School of Computer Science, Hangzhou Dianzi University, Hangzhou 310018, China

More Information

Corresponding author: WANG Rubin

摘要

摘要: 该文系统总结了作者团队在脑科学领域内提出的神经能量理论与方法,以及力学与神经能量理论之间的内在联系.着重介绍了如何运用分析动力学的思想构建一个与H-H模型等效的W-Z神经元模型.并以此为基础,在神经科学领域内提出了以神经能量为核心的大尺度神经科学模型和大脑全局神经编码的理论框架.在包括视知觉等多个感知觉神经系统的信息处理、大脑的智力探索以及预测神经元新的工作机制、解释神经科学难以解释的实验现象等方面,证实了这个新颖的神经元模型所展现出来的独特功能与优势.由于可塑性是认知神经科学与智能行为的核心,通过蛋白质分子机器的经典力学分析,进一步阐明了神经元的可塑性和神经发育不仅仅只是生物化学反应过程,力学的作用与贡献也是不可或缺的重要因素.表明了力学科学在神经科学、生命科学中的研究思想及其内在逻辑的深远影响.这些研究对于今后推动实验神经科学与理论神经科学的融合,摒弃神经科学领域中还原论与整体论研究方法中的不足,并将它们各自的优点进行有效地整合,促进力学科学的理论与方法的渗透是极其重要的.
- 脑科学 /
- 力学 /
- 神经元模型 /
- 大尺度神经科学 /
- 神经动力学 /
- 神经能量理论
Abstract: This review article systematically summarizes the neural energy theory and methods proposed by our team in the field of brain science, and the internal relationship between mechanics and neural energy theory. This paper introduces how to construct an equivalent W-Z neuron model with the H-H model using the idea of analytic dynamics. Based on this, a large-scale neural model with neural energy as the core and a theoretical framework of global neural coding are proposed in the field of neuroscience. The unique functions and advantages of this novel neuron model are confirmed in the aspects of information processing, including visual perception, brain intelligence exploration, prediction of new working mechanisms of neurons and explanation of experimental phenomena challenging to explain in neuroscience. Because plasticity is the core of cognitive neuroscience and intelligent behavior, through the classical mechanical analysis of protein molecular machines, it is further clarified that the plasticity and neurodevelopment of neurons are not only biochemical reaction processes but also the role and contribution of mechanics are indispensable and important factors. It shows that the research thought of mechanics science in neuroscience and life science and its profound influence on internal logic. These studies will promote the integration of experimental neuroscience and theoretical neuroscience in the future, abandon the shortcomings in the research methods of reductionism and holism in the field of neuroscience, and integrate their respective advantages effectively. It is extremely important to promote the penetration of theories and methods of mechanical science.
- brain science /
- mechanics /
- neuron models /
- large scale neuroscience /
- neurodynamics /
- theory of neural energy

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参考文献(193)

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