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扫描过程中的头部运动与结构协方差网络。

In-scanner head motion and structural covariance networks.

作者信息

Pardoe Heath R, Martin Samantha P

机构信息

Comprehensive Epilepsy Center, Department of Neurology, NYU Grossman School of Medicine, New York, New York, USA.

Florey Institute of Neuroscience and Mental Health, Melbourne, Australia.

出版信息

Hum Brain Mapp. 2022 Oct 1;43(14):4335-4346. doi: 10.1002/hbm.25957. Epub 2022 May 20.

DOI:10.1002/hbm.25957
PMID:35593313
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9435006/
Abstract

In-scanner head motion systematically reduces estimated regional gray matter volumes obtained from structural brain MRI. Here, we investigate how head motion affects structural covariance networks that are derived from regional gray matter volumetric estimates. We acquired motion-affected and low-motion whole brain T1-weighted MRI in 29 healthy adult subjects and estimated relative regional gray matter volumes using a voxel-based morphometry approach. Structural covariance network analyses were undertaken while systematically increasing the number of included motion-affected scans. We demonstrate that the standard deviation in regional gray matter estimates increases as the number of motion-affected scans increases. This increases pairwise correlations between regions, a key determinant for construction of structural covariance networks. We further demonstrate that head motion systematically alters graph theoretic metrics derived from these networks. Finally, we present evidence that weighting correlations using image quality metrics can mitigate the effects of head motion. Our findings suggest that in-scanner head motion is a source of error that violates the assumption that structural covariance networks reflect neuroanatomical connectivity between brain regions. Results of structural covariance studies should be interpreted with caution, particularly when subject groups are likely to move their heads in the scanner.

摘要

扫描过程中的头部运动系统性地减少了从结构性脑磁共振成像(MRI)获得的估计区域灰质体积。在此,我们研究头部运动如何影响从区域灰质体积估计值推导出来的结构协方差网络。我们获取了29名健康成年受试者受运动影响和低运动的全脑T1加权MRI,并使用基于体素的形态测量方法估计相对区域灰质体积。在系统性增加纳入的受运动影响扫描数量的同时进行结构协方差网络分析。我们证明,随着受运动影响扫描数量的增加,区域灰质估计值的标准差会增大。这增加了区域之间的成对相关性,而这是构建结构协方差网络的一个关键决定因素。我们进一步证明,头部运动会系统性地改变从这些网络推导出来的图论指标。最后,我们提供证据表明,使用图像质量指标对相关性进行加权可以减轻头部运动的影响。我们的研究结果表明,扫描过程中的头部运动是一个误差来源,它违反了结构协方差网络反映脑区之间神经解剖连接性这一假设。结构协方差研究的结果应谨慎解释,特别是当受试群体可能在扫描仪中移动头部时。

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