一个可解释的几何加权图注意网络识别与步态障碍相关的功能网络。

Favour Nerrise, Qingyu Zhao, Kathleen L Poston, Kilian M Pohl, Ehsan Adeli
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引用次数: 0

摘要

帕金森病(PD)的标志性症状之一是姿势反射的逐渐丧失,最终导致步态困难和平衡问题。识别与步态障碍相关的脑功能中断对于更好地了解PD运动进展至关重要,从而促进更有效和个性化治疗的发展。在这项工作中,我们提出了一个可解释的、几何的、加权图的注意神经网络(xGW-GAT)来识别预测PD患者步态困难进展的功能网络。xGW-GAT预测mds -统一PD评定量表(MDS-UPDRS)的多等级步态障碍。我们的计算和数据效率模型将功能连接体表示为黎曼流形上的对称正定(SPD)矩阵,以显式编码整个连接体的成对相互作用,在此基础上,我们学习了一个产生个人和群体级别可解释性的注意掩模。xGW-GAT应用于PD患者的静息状态功能MRI (rs-fMRI)数据集,确定了PD患者与步态障碍相关的功能连接模式,并提供了与运动障碍相关的功能子网络的可解释性解释。我们的模型成功地超越了几种现有的方法,同时揭示了临床相关的连接模式。源代码可从https://github.com/favour-nerrise/xGW-GAT获得。
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An Explainable Geometric-Weighted Graph Attention Network for Identifying Functional Networks Associated with Gait Impairment.

One of the hallmark symptoms of Parkinson's Disease (PD) is the progressive loss of postural reflexes, which eventually leads to gait difficulties and balance problems. Identifying disruptions in brain function associated with gait impairment could be crucial in better understanding PD motor progression, thus advancing the development of more effective and personalized therapeutics. In this work, we present an explainable, geometric, weighted-graph attention neural network (xGW-GAT) to identify functional networks predictive of the progression of gait difficulties in individuals with PD. xGW-GAT predicts the multi-class gait impairment on the MDS-Unified PD Rating Scale (MDS-UPDRS). Our computational- and data-efficient model represents functional connectomes as symmetric positive definite (SPD) matrices on a Riemannian manifold to explicitly encode pairwise interactions of entire connectomes, based on which we learn an attention mask yielding individual- and group-level explainability. Applied to our resting-state functional MRI (rs-fMRI) dataset of individuals with PD, xGW-GAT identifies functional connectivity patterns associated with gait impairment in PD and offers interpretable explanations of functional subnetworks associated with motor impairment. Our model successfully outperforms several existing methods while simultaneously revealing clinically-relevant connectivity patterns. The source code is available at https://github.com/favour-nerrise/xGW-GAT.

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