通过 Hodge-Laplacian 处理大脑功能数据的异构图卷积神经网络

Jinghan Huang, Moo K Chung, Anqi Qiu
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摘要

本研究提出了一种新型异构图卷积神经网络(HGCNN),用于处理区域和跨区域级别的复杂脑部 fMRI 数据。我们通过引入 k-th Hodge-Laplacian (HL) 算子,介绍了异构图谱滤波器的通用公式。特别是,我们提出了 HL 频谱滤波器的拉盖尔多项式近似值,并证明其在图上的空间定位与多项式阶数有关。此外,基于单纯形图上边界算子的双射属性,我们引入了一种通用拓扑图池化(TGPool)方法,该方法可用于任意维度的单纯形图。本研究设计了 HL-节点、HL-边缘和 HL-HGCNN 神经网络,分别学习图节点、边缘和两者的信号表示。我们的实验采用青少年大脑认知发展(ABCD;n=7693)的 fMRI 来预测一般智力。我们的结果表明,当大脑功能连接被视为特征时,HL-边网络比 HL-节点网络更具优势。HL-HGCNN 优于最先进的图神经网络(GNN)方法,如 GAT、BrainGNN、dGCN、BrainNetCNN 和 Hypergraph NN。从 HL-HGCNN 中学习到的功能连接特征对于解释与一般智能相关的神经回路很有意义。
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Heterogeneous Graph Convolutional Neural Network via Hodge-Laplacian for Brain Functional Data.

This study proposes a novel heterogeneous graph convolutional neural network (HGCNN) to handle complex brain fMRI data at regional and across-region levels. We introduce a generic formulation of spectral filters on heterogeneous graphs by introducing the k-th Hodge-Laplacian (HL) operator. In particular, we propose Laguerre polynomial approximations of HL spectral filters and prove that their spatial localization on graphs is related to the polynomial order. Furthermore, based on the bijection property of boundary operators on simplex graphs, we introduce a generic topological graph pooling (TGPool) method that can be used at any dimensional simplices. This study designs HL-node, HL-edge, and HL-HGCNN neural networks to learn signal representation at a graph node, edge levels, and both, respectively. Our experiments employ fMRI from the Adolescent Brain Cognitive Development (ABCD; n=7693) to predict general intelligence. Our results demonstrate the advantage of the HL-edge network over the HL-node network when functional brain connectivity is considered as features. The HL-HGCNN outperforms the state-of-the-art graph neural networks (GNNs) approaches, such as GAT, BrainGNN, dGCN, BrainNetCNN, and Hypergraph NN. The functional connectivity features learned from the HL-HGCNN are meaningful in interpreting neural circuits related to general intelligence.

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