体素级功能成像下的有监督大脑节点和网络构建

Wanwan Xu, Selena Wang, Chichun Tan, Xilin Shen, Wenjing Luo, Todd Constable, Tianxi Li, Yize Zhao
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摘要

最近,在理解与行为相关的大脑功能组织方面取得了举足轻重的进展,尤其是在开发基于大脑连接性的预测模型方面。这一领域的传统方法通常包括两个步骤:首先从预定义的脑区构建连接矩阵,然后将这些连接与行为或临床结果联系起来。然而,这些采用无监督节点分区的方法在独立建立连接性的情况下预测结果的效率很低。在本文中,我们介绍了 "监督脑节点划分"(Supervised Brain Parcellation,SBP),这是一种由下游预测任务提供信息的脑节点划分方案。以静息态或认知任务下生成的体素级功能时程为输入,我们的方法将体素聚类为节点,使节点间连接与行为结果之间的相关性最大化,同时也兼顾了节点内的同质性。我们使用青少年大脑认知发展(ABCD)研究和人类连接组计划(HCP)的静息态和任务型 fMRI 数据对 SBP 方法进行了评估。我们的分析表明,在各种脑图谱下,与传统的分步法相比,SBP 能显著提高基于连接组的样本外预测性能。这一进步有望增强我们对大脑功能结构与行为的理解,并为临床应用建立更多信息丰富的网络神经标记。
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Supervised brain node and network construction under voxel-level functional imaging
Recent advancements in understanding the brain's functional organization related to behavior have been pivotal, particularly in the development of predictive models based on brain connectivity. Traditional methods in this domain often involve a two-step process by first constructing a connectivity matrix from predefined brain regions, and then linking these connections to behaviors or clinical outcomes. However, these approaches with unsupervised node partitions predict outcomes inefficiently with independently established connectivity. In this paper, we introduce the Supervised Brain Parcellation (SBP), a brain node parcellation scheme informed by the downstream predictive task. With voxel-level functional time courses generated under resting-state or cognitive tasks as input, our approach clusters voxels into nodes in a manner that maximizes the correlation between inter-node connections and the behavioral outcome, while also accommodating intra-node homogeneity. We rigorously evaluate the SBP approach using resting-state and task-based fMRI data from both the Adolescent Brain Cognitive Development (ABCD) study and the Human Connectome Project (HCP). Our analyses show that SBP significantly improves out-of-sample connectome-based predictive performance compared to conventional step-wise methods under various brain atlases. This advancement holds promise for enhancing our understanding of brain functional architectures with behavior and establishing more informative network neuromarkers for clinical applications.
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