FedBrain:基于连接体的脑成像分析的图神经网络联合训练。

Yi Yang, Han Xie, Hejie Cui, Carl Yang
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引用次数: 0

摘要

神经成像技术的最新进展引发了人们对了解解剖学感兴趣区(ROIs)之间复杂相互作用的日益浓厚的兴趣,这些相互作用形成的大脑网络在神经模式发现和疾病诊断等各种临床任务中发挥着至关重要的作用。近年来,图神经网络(GNN)已成为分析网络数据的强大工具。然而,由于数据采集的复杂性和监管限制,脑网络研究的规模仍然有限,而且往往局限于本地机构。这些限制极大地挑战了 GNN 模型捕捉有用神经回路模式并提供稳健下游性能的能力。作为一种分布式机器学习范例,联合学习(FL)提供了一种很有前景的解决方案,它能在不共享数据的情况下,实现本地机构(即客户)之间的协作学习,从而解决资源限制和隐私问题。虽然数据异构问题已在最近的联合学习文献中得到了广泛研究,但跨机构脑网络分析面临着独特的数据异构挑战,即本地神经影像研究中不一致的 ROI 剖分系统和不同的预测神经回路模式。为此,我们提出了基于 GNN 的个性化 FL 框架 FedBrain,该框架考虑到了脑网络数据的独特属性。具体来说,我们提出了一种联合图集映射机制,以克服不同 ROI 图集系统产生的脑网络特征和结构异质性,并提出了一种以临床先验知识为指导的聚类方法,以解决不同患者群体、神经成像模式和临床结果的不同预测神经回路模式。与现有的 FL 策略相比,我们的方法表现出更优越、更稳定的性能,展示了其在跨机构基于连接体的脑成像分析中的强大潜力和通用性。具体实施请点击此处。
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FedBrain: Federated Training of Graph Neural Networks for Connectome-based Brain Imaging Analysis.

Recent advancements in neuroimaging techniques have sparked a growing interest in understanding the complex interactions between anatomical regions of interest (ROIs), forming into brain networks that play a crucial role in various clinical tasks, such as neural pattern discovery and disorder diagnosis. In recent years, graph neural networks (GNNs) have emerged as powerful tools for analyzing network data. However, due to the complexity of data acquisition and regulatory restrictions, brain network studies remain limited in scale and are often confined to local institutions. These limitations greatly challenge GNN models to capture useful neural circuitry patterns and deliver robust downstream performance. As a distributed machine learning paradigm, federated learning (FL) provides a promising solution in addressing resource limitation and privacy concerns, by enabling collaborative learning across local institutions (i.e., clients) without data sharing. While the data heterogeneity issues have been extensively studied in recent FL literature, cross-institutional brain network analysis presents unique data heterogeneity challenges, that is, the inconsistent ROI parcellation systems and varying predictive neural circuitry patterns across local neuroimaging studies. To this end, we propose FedBrain, a GNN-based personalized FL framework that takes into account the unique properties of brain network data. Specifically, we present a federated atlas mapping mechanism to overcome the feature and structure heterogeneity of brain networks arising from different ROI atlas systems, and a clustering approach guided by clinical prior knowledge to address varying predictive neural circuitry patterns regarding different patient groups, neuroimaging modalities and clinical outcomes. Compared to existing FL strategies, our approach demonstrates superior and more consistent performance, showcasing its strong potential and generalizability in cross-institutional connectome-based brain imaging analysis. The implementation is available here.

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FedBrain: Federated Training of Graph Neural Networks for Connectome-based Brain Imaging Analysis. Generating new drug repurposing hypotheses using disease-specific hypergraphs. Impact of Measurement Noise on Genetic Association Studies of Cardiac Function. Imputation of race and ethnicity categories using genetic ancestry from real-world genomic testing data. intCC: An efficient weighted integrative consensus clustering of multimodal data.
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