动态图网络可能有助于预测不同脑肿瘤类型的表型

A. Meyer-Baese, Kerstin Juetten, Uwe Meyer-Baese, A. Stadlbauer, T. Kinfe, Chuh-Hyoun Na
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引用次数: 0

摘要

弥漫性浸润性胶质瘤被认为是一种全身性脑疾病,它会对肿瘤部位以外的大脑功能和结构完整性产生改变。这些变化是大规模神经回路之间动态相互作用的结果。描述这些相互作用的性质一直是一项具有挑战性的任务,但对胶质瘤疾病的进化很重要。现代动态图网络理论技术和控制理论应用于这些结构和功能网络,为理解健康对照和胶质瘤患者的动态特性和差异开辟了新的研究途径。研究表明,可控性与提供大脑如何在认知状态之间导航的机制解释有关。我们认为这也与描述胶质瘤的连接组改变以及亚型和健康对照之间的差异有关。控制这些网络并影响其任何状态所需的节点称为驱动节点。我们确定了异脱氢酶突变(IDHmut)和野生型(IDHwt)患者和健康对照者的静息状态功能连接(FC)和基于弥散核磁共振的结构连接(SC)(包括边权(EW)和分数各向异性(FA))网络的默认模式网络(DMN)的驱动节点。我们的研究结果表明,健康对照对FC和SC都具有更好的可控性,并且结构连接组动力学畸变在胶质瘤患者中比功能连接组改变更为明显。
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Dynamical graph networks may aid in phenotyping prognostically different brain tumor types
Diffuse infiltrative glioma are considered as a systemic brain disorder and produce alterations on cerebral functional and structural integrity beyond the tumor location. These alterations are the result of the dynamic interplay between large-scale neural circuits. Describing the nature of these interactions has been a challenging task yet important for glioma disease evolution. Modern dynamic graph network theory techniques and control theory applied to these structural and functional networks opens a new research avenue for understanding the dynamical properties and differences between healthy controls and glioma patients. It has been shown that controllability is relevant for providing the mechanistic explanation of how the brain navigates between cognitive states. We believe that it is also relevant for describing the connectomic alterations in glioma and the differences among subtypes and healthy controls. The nodes that are needed to control these networks and influence them to any state are called driver nodes. We determined the driver nodes of the Default-Mode Network (DMN) for resting-state functional connectivity (FC) and diffusion-MRI-based structural connectivity (SC) (comprising edge-weight (EW) and fractional anisotropy (FA)) networks in isodehydrogenase mutated (IDHmut) and wildtype (IDHwt) patients and healthy controls. Our results show that healthy controls have a better controllability for both FC and SC, and that structural connectomic dynamical aberrations are more pronounced in glioma patients than functional connectomic alterations.
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