大脑中复杂网络的图论分析。

Cornelis J Stam, Jaap C Reijneveld
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引用次数: 954

摘要

自从发现小世界和无标度网络以来,从网络的角度研究复杂系统已经迈出了巨大的步伐。近年来,人们对复杂网络的许多重要性质进行了刻画。特别是,在理解网络的结构特性与这些网络上发生的动力学性质之间的关系方面取得了重大进展。例如,耦合振荡器的复杂网络的“同步性”可以通过图谱分析来确定。复杂网络理论的这些发展激发了神经科学领域的新应用。基于功能磁共振成像、脑电图和脑磁图,图分析已被用于神经网络模型、解剖连接和功能连接的研究。这些研究表明,人类大脑可以被建模为一个复杂的网络,在解剖和功能连接层面上都可能有一个小的世界结构。假设这种小世界结构反映了与快速同步和信息传输、最低布线成本以及本地处理和全局集成之间的平衡相关的最佳情况。功能网络的拓扑结构可能受到遗传和解剖因素的限制,但可以在任务中进行修改。还有越来越多的证据表明,阿尔茨海默病、精神分裂症、脑瘤和癫痫等各种类型的脑部疾病可能与功能网络拓扑结构偏离最佳小世界模式有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Graph theoretical analysis of complex networks in the brain.

Graph theoretical analysis of complex networks in the brain.

Graph theoretical analysis of complex networks in the brain.

Graph theoretical analysis of complex networks in the brain.

Since the discovery of small-world and scale-free networks the study of complex systems from a network perspective has taken an enormous flight. In recent years many important properties of complex networks have been delineated. In particular, significant progress has been made in understanding the relationship between the structural properties of networks and the nature of dynamics taking place on these networks. For instance, the 'synchronizability' of complex networks of coupled oscillators can be determined by graph spectral analysis. These developments in the theory of complex networks have inspired new applications in the field of neuroscience. Graph analysis has been used in the study of models of neural networks, anatomical connectivity, and functional connectivity based upon fMRI, EEG and MEG. These studies suggest that the human brain can be modelled as a complex network, and may have a small-world structure both at the level of anatomical as well as functional connectivity. This small-world structure is hypothesized to reflect an optimal situation associated with rapid synchronization and information transfer, minimal wiring costs, as well as a balance between local processing and global integration. The topological structure of functional networks is probably restrained by genetic and anatomical factors, but can be modified during tasks. There is also increasing evidence that various types of brain disease such as Alzheimer's disease, schizophrenia, brain tumours and epilepsy may be associated with deviations of the functional network topology from the optimal small-world pattern.

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