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野生型和R6/2小鼠行为模式中不可预测性的神经关联

Neural correlates of unpredictability in behavioral patterns of wild-type and R6/2 mice.

作者信息

Hong S Lee, Barton Scott J, Rebec George V

出版信息

Commun Integr Biol. 2012 May 1;5(3):259-61. doi: 10.4161/cib.19782.

DOI:10.4161/cib.19782
PMID:22896787
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3419109/
Abstract

This paper expands on recent findings that link dynamic patterns of striatal activity with patterns of movement and exploration in wild-type and transgenic mice (R6/2) that model Huntington disease (HD), a fatally inherited neurological condition. Here, with HD as a backdrop, we further develop the concept of entropy conservation in brain and behavior. In particular, we propose that entropy conservation could serve as a rule that guides the process of redistributing brain activity dynamics in order to alter behavior, allowing the adaptation to an ever-changing external environment. This concept is further linked to recent neuroimaging studies in human aging, building a new bridge between our recent findings of entropy conservation and the extant literature.

摘要

本文扩展了近期的研究发现,这些发现将野生型和转基因(R6/2)小鼠(模拟亨廷顿舞蹈病(HD),一种致命的遗传性神经疾病)纹状体活动的动态模式与运动和探索模式联系起来。在此,以HD为背景,我们进一步发展了大脑和行为中熵守恒的概念。特别是,我们提出熵守恒可以作为一条规则,指导大脑活动动态重新分配的过程,从而改变行为,以适应不断变化的外部环境。这一概念进一步与近期关于人类衰老的神经影像学研究相关联,在我们关于熵守恒的最新发现与现有文献之间搭建了一座新的桥梁。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a519/3419109/0739bce3d7b6/cib-5-259-g1.jpg

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