Investigating cognitive ability using action-based models of structural brain networks

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Viplove Arora;Enrico Amico;Joaquín Goñi;Mario Ventresca
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引用次数: 0

Abstract

Recent developments in network neuroscience have highlighted the importance of developing techniques for analysing and modelling brain networks. A particularly powerful approach for studying complex neural systems is to formulate generative models that use wiring rules to synthesize networks closely resembling the topology of a given connectome. Successful models can highlight the principles by which a network is organized (identify structural features that arise from wiring rules versus those that emerge) and potentially uncover the mechanisms by which it grows and develops. Previous research has shown that such models can validate the effectiveness of spatial embedding and other (non-spatial) wiring rules in shaping the network topology of the human connectome. In this research, we propose variants of the action-based model that combine a variety of generative factors capable of explaining the topology of the human connectome. We test the descriptive validity of our models by evaluating their ability to explain between-subject variability. Our analysis provides evidence that geometric constraints are vital for connectivity between brain regions, and an action-based model relying on both topological and geometric properties can account for between-subject variability in structural network properties. Further, we test correlations between parameters of subject-optimized models and various measures of cognitive ability and find that higher cognitive ability is associated with an individual's tendency to form long-range or non-local connections.
利用基于行为的脑结构网络模型研究认知能力
网络神经科学的最新发展突出了开发分析和建模大脑网络的技术的重要性。研究复杂神经系统的一种特别强大的方法是建立生成模型,使用布线规则来合成与给定连接体拓扑结构非常相似的网络。成功的模型可以突出网络的组织原则(识别由布线规则产生的结构特征与出现的结构特征),并可能揭示网络增长和发展的机制。先前的研究表明,这种模型可以验证空间嵌入和其他(非空间)布线规则在塑造人类连接体网络拓扑方面的有效性。在这项研究中,我们提出了基于动作的模型的变体,该模型结合了能够解释人类连接体拓扑结构的各种生成因素。我们通过评估模型解释受试者之间可变性的能力来测试模型的描述性有效性。我们的分析提供了证据,证明几何约束对大脑区域之间的连接至关重要,基于拓扑和几何特性的动作模型可以解释结构网络特性的受试者之间的可变性。此外,我们测试了受试者优化模型的参数与认知能力的各种测量之间的相关性,发现较高的认知能力与个体形成长期或非局部联系的倾向有关。
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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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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