GAT-LI: a graph attention network based learning and interpreting method for functional brain network classification

GAT-LI: a graph attention network based learning and interpreting method for functional brain network classification

Autism spectrum disorders (ASD) imply a spectrum of symptoms rather than a single phenotype. ASD could affect brain connectivity at different degree based on the severity of the symptom. Given their excellent learning capability, graph neural networks (GNN) methods have recently been used to uncover...

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Bibliographic Details
Published in:BMC bioinformatics Vol. 22; no. Suppl 10; pp. 1 - 379
Main Authors: Hu, Jinlong, Cao, Lijie, Li, Tenghui, Dong, Shoubin, Li, Ping
Format: Journal Article
Language:English
Published: London BioMed Central Ltd 22-07-2021
BioMed Central
BMC
Subjects:
Analysis
Autism
Biomedical data
Brain
Classification
Construction methods
Decision analysis
Deep learning
Disorders
Functional brain networks
Graph attention networks
Graph neural networks
Graph representations
Graph theory
Graphical representations
Health aspects
Identification methods
Learning
Machine learning
Mental disorders
Methodology
Methods
Model interpretation
Network analysis
Neural networks
Phenotypes
Resting-state functional connectivity data
Signs and symptoms
Time series
China
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Summary:Autism spectrum disorders (ASD) imply a spectrum of symptoms rather than a single phenotype. ASD could affect brain connectivity at different degree based on the severity of the symptom. Given their excellent learning capability, graph neural networks (GNN) methods have recently been used to uncover functional connectivity patterns and biological mechanisms in neuropsychiatric disorders, such as ASD. However, there remain challenges to develop an accurate GNN learning model and understand how specific decisions of these graph models are made in brain network analysis. In this paper, we propose a graph attention network based learning and interpreting method, namely GAT-LI, which learns to classify functional brain networks of ASD individuals versus healthy controls (HC), and interprets the learned graph model with feature importance. Specifically, GAT-LI includes a graph learning stage and an interpreting stage. First, in the graph learning stage, a new graph attention network model, namely GAT2, uses graph attention layers to learn the node representation, and a novel attention pooling layer to obtain the graph representation for functional brain network classification. We experimentally compared GAT2 model's performance on the ABIDE I database from 1035 subjects against the classification performances of other well-known models, and the results showed that the GAT2 model achieved the best classification performance. We experimentally compared the influence of different construction methods of brain networks in GAT2 model. We also used a larger synthetic graph dataset with 4000 samples to validate the utility and power of GAT2 model. Second, in the interpreting stage, we used GNNExplainer to interpret learned GAT2 model with feature importance. We experimentally compared GNNExplainer with two well-known interpretation methods including Saliency Map and DeepLIFT to interpret the learned model, and the results showed GNNExplainer achieved the best interpretation performance. We further used the interpretation method to identify the features that contributed most in classifying ASD versus HC. We propose a two-stage learning and interpreting method GAT-LI to classify functional brain networks and interpret the feature importance in the graph model. The method should also be useful in the classification and interpretation tasks for graph data from other biomedical scenarios.
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ISSN:1471-2105
1471-2105
DOI:10.1186/s12859-021-04295-1