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引用次数: 0
摘要
通过核磁共振成像体积测量法测量的神经变性被认为是一种潜在的阿尔茨海默病(AD)生物标志物,但由于缺乏特异性,其效用受到了限制。量化全脑而非局部神经变性的空间模式可能有助于解决这一问题。在这项研究中,我们转而采用基于网络的分析方法,并扩展了图嵌入算法,以研究用结构性核磁共振成像测量的体积变化相关性在数年时间尺度上的形态连接性。我们用多重随机秭归图框架建立数据模型,并修改和实施了早先提出的多重图嵌入算法,以估算网络的低维嵌入。我们的算法版本保证了有意义的有限样本结果,并能根据特定人群的网络模式和特定受试者的负载估计最大似然边缘概率。此外,我们还提出并实施了一种新颖的统计测试程序,用于在考虑混杂因素后分析组间差异,并定位 AD 神经变性过程中的重要结构。通过对最大统计量进行置换检验,将族内误差率控制在 5%。我们的分析结果表明,我们发现的网络以与 AD 神经变性相关的已知结构为主,这表明该框架有望用于研究 AD。此外,我们还发现了该领域传统方法无法发现的网络结构图元。
Applying Joint Graph Embedding to Study Alzheimer's Neurodegeneration Patterns in Volumetric Data.
Neurodegeneration measured through volumetry in MRI is recognized as a potential Alzheimer's Disease (AD) biomarker, but its utility is limited by lack of specificity. Quantifying spatial patterns of neurodegeneration on a whole brain scale rather than locally may help address this. In this work, we turn to network based analyses and extend a graph embedding algorithm to study morphometric connectivity from volume-change correlations measured with structural MRI on the timescale of years. We model our data with the multiple random eigengraphs framework, as well as modify and implement a multigraph embedding algorithm proposed earlier to estimate a low dimensional embedding of the networks. Our version of the algorithm guarantees meaningful finite-sample results and estimates maximum likelihood edge probabilities from population-specific network modes and subject-specific loadings. Furthermore, we propose and implement a novel statistical testing procedure to analyze group differences after accounting for confounders and locate significant structures during AD neurodegeneration. Family-wise error rate is controlled at 5% using permutation testing on the maximum statistic. We show that results from our analysis reveal networks dominated by known structures associated to AD neurodegeneration, indicating the framework has promise for studying AD. Furthermore, we find network-structure tuples that are not found with traditional methods in the field.
期刊介绍:
Neuroinformatics publishes original articles and reviews with an emphasis on data structure and software tools related to analysis, modeling, integration, and sharing in all areas of neuroscience research. The editors particularly invite contributions on: (1) Theory and methodology, including discussions on ontologies, modeling approaches, database design, and meta-analyses; (2) Descriptions of developed databases and software tools, and of the methods for their distribution; (3) Relevant experimental results, such as reports accompanie by the release of massive data sets; (4) Computational simulations of models integrating and organizing complex data; and (5) Neuroengineering approaches, including hardware, robotics, and information theory studies.