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人类连接组中的团块和空洞。

Cliques and cavities in the human connectome.

作者信息

Sizemore Ann E, Giusti Chad, Kahn Ari, Vettel Jean M, Betzel Richard F, Bassett Danielle S

机构信息

Department of Bioengineering, University of Pennsylvania, Philadelphia, PA, USA.

Broad Institute, Harvard University and the Massachusetts Institute of Technology, Cambridge, MA, USA.

出版信息

J Comput Neurosci. 2018 Feb;44(1):115-145. doi: 10.1007/s10827-017-0672-6. Epub 2017 Nov 16.

DOI:10.1007/s10827-017-0672-6
PMID:29143250
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5769855/
Abstract

Encoding brain regions and their connections as a network of nodes and edges captures many of the possible paths along which information can be transmitted as humans process and perform complex behaviors. Because cognitive processes involve large, distributed networks of brain areas, principled examinations of multi-node routes within larger connection patterns can offer fundamental insights into the complexities of brain function. Here, we investigate both densely connected groups of nodes that could perform local computations as well as larger patterns of interactions that would allow for parallel processing. Finding such structures necessitates that we move from considering exclusively pairwise interactions to capturing higher order relations, concepts naturally expressed in the language of algebraic topology. These tools can be used to study mesoscale network structures that arise from the arrangement of densely connected substructures called cliques in otherwise sparsely connected brain networks. We detect cliques (all-to-all connected sets of brain regions) in the average structural connectomes of 8 healthy adults scanned in triplicate and discover the presence of more large cliques than expected in null networks constructed via wiring minimization, providing architecture through which brain network can perform rapid, local processing. We then locate topological cavities of different dimensions, around which information may flow in either diverging or converging patterns. These cavities exist consistently across subjects, differ from those observed in null model networks, and - importantly - link regions of early and late evolutionary origin in long loops, underscoring their unique role in controlling brain function. These results offer a first demonstration that techniques from algebraic topology offer a novel perspective on structural connectomics, highlighting loop-like paths as crucial features in the human brain's structural architecture.

摘要

将大脑区域及其连接编码为节点和边的网络,能够捕捉到人类在处理和执行复杂行为时信息可能传输的许多路径。由于认知过程涉及大脑区域的大型分布式网络,对更大连接模式内的多节点路径进行有原则的研究,可以为大脑功能的复杂性提供基本见解。在这里,我们研究了既可以执行局部计算的紧密连接的节点组,以及允许并行处理的更大交互模式。要找到这样的结构,我们必须从仅考虑成对交互转向捕捉更高阶关系,这些关系自然地用代数拓扑语言来表达。这些工具可用于研究中尺度网络结构,这些结构源于在其他稀疏连接的大脑网络中称为团的紧密连接子结构的排列。我们在对8名健康成年人进行三次扫描得到的平均结构连接组中检测团(大脑区域的全连接集),并发现与通过布线最小化构建的空网络相比,存在更多的大团,这为大脑网络执行快速局部处理提供了架构。然后,我们定位不同维度的拓扑空洞,信息可能以发散或收敛模式在其周围流动。这些空洞在不同受试者中一致存在,与在空模型网络中观察到的不同,而且重要的是,它们在长环中连接了早期和晚期进化起源的区域,突出了它们在控制大脑功能方面的独特作用。这些结果首次证明,代数拓扑技术为结构连接组学提供了一个新视角,突出了环状路径是人类大脑结构架构的关键特征。

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