Bifurcation in space: Emergence of functional modularity in the neocortex.

bioRxiv : the preprint server for biology Pub Date : 2024-12-21 DOI:10.1101/2023.06.04.543639

Xiao-Jing Wang, Junjie Jiang, Roxana Zeraati, Ulises Pereira-Obilinovic, Aldo Battista, Julien Vezoli, Henry Kennedy

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Abstract

How does functional modularity emerge in a cortex composed of repeats of a canonical local circuit? Focusing on distributed working memory, we show that a rigorous description of bifurcation in space describes the emergence of modularity. A connectome-based model of monkey cortex displays bifurcation in space during decision-making and working memory, demonstrating this new concept's generality. In a generative model and multi-regional cortex models of both macaque monkey and mouse, we found an inverted-V-shaped profile of neuronal timescales across the cortical hierarchy during working memory, providing an experimentally testable prediction of modularity. The cortex displays simultaneously many bifurcations in space, so that the corresponding modules could potentially subserve distinct internal mental processes. Therefore, a distributed process subserves the brain's functional specificity. We propose that bifurcation in space, resulting from connectivity and macroscopic gradients of neurobiological properties across the cortex, represents a fundamental principle for understanding the brain's modular organization.

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空间分叉：新皮质功能模块化的出现。

功能模块化是如何在由典型局部电路结构的重复组成的多区域皮层中出现的？我们通过关注工作记忆（一种核心认知功能）的神经编码来研究这个问题。在这里，我们报道了一种被称为“空间分叉”的机制，并表明其显著特征是空间定位的“临界减慢”，导致在工作记忆过程中，神经元时间常数沿皮层层次呈倒V形分布。这一现象在基于连接体的小鼠和猴子皮层大规模模型中得到了证实，为评估工作记忆表示是否是模块化的提供了一个实验可测试的预测。空间中的许多分叉可以解释不同活动模式的出现，这些活动模式可能用于不同的认知功能。这项工作表明，由于大脑皮层神经生物学特性的宏观梯度，分布式心理表征与功能特异性相兼容，提出了理解大脑模块化组织的一般原则。

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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bioRxiv : the preprint server for biology

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