Disease prediction using graph convolutional networks: Application to Autism Spectrum Disorder and Alzheimer’s disease

•First application of graph convolutional networks for brain analysis in populations.•Graph based population model that leverages imaging and non-imaging data.•Experiments on two large and challenging databases: ABIDE and ADNI.•Extensive evaluation of all the main components of the method.•State of...

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Veröffentlicht in:	Medical image analysis 2018-08, Vol.48, p.117-130
Hauptverfasser:	Parisot, Sarah, Ktena, Sofia Ira, Ferrante, Enzo, Lee, Matthew, Guerrero, Ricardo, Glocker, Ben, Rueckert, Daniel
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Alzheimer Disease - diagnostic imaging Alzheimer's disease Artificial neural networks Autism Autism Spectrum Disorder Autism Spectrum Disorder - diagnostic imaging Brain Classification Convolutional codes Data processing Databases, Factual Evaluation Graph convolutional networks Graph theory Graphical representations Graphs Humans Medical imaging Neural Networks (Computer) Neuroimaging Neuroimaging - methods Nodes Populations Predictive Value of Tests Semi-supervised classification Spectral theory
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container_title	Medical image analysis
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creator	Parisot, Sarah Ktena, Sofia Ira Ferrante, Enzo Lee, Matthew Guerrero, Ricardo Glocker, Ben Rueckert, Daniel
description	•First application of graph convolutional networks for brain analysis in populations.•Graph based population model that leverages imaging and non-imaging data.•Experiments on two large and challenging databases: ABIDE and ADNI.•Extensive evaluation of all the main components of the method.•State of the art performance on both databases. [Display omitted] Graphs are widely used as a natural framework that captures interactions between individual elements represented as nodes in a graph. In medical applications, specifically, nodes can represent individuals within a potentially large population (patients or healthy controls) accompanied by a set of features, while the graph edges incorporate associations between subjects in an intuitive manner. This representation allows to incorporate the wealth of imaging and non-imaging information as well as individual subject features simultaneously in disease classification tasks. Previous graph-based approaches for supervised or unsupervised learning in the context of disease prediction solely focus on pairwise similarities between subjects, disregarding individual characteristics and features, or rather rely on subject-specific imaging feature vectors and fail to model interactions between them. In this paper, we present a thorough evaluation of a generic framework that leverages both imaging and non-imaging information and can be used for brain analysis in large populations. This framework exploits Graph Convolutional Networks (GCNs) and involves representing populations as a sparse graph, where its nodes are associated with imaging-based feature vectors, while phenotypic information is integrated as edge weights. The extensive evaluation explores the effect of each individual component of this framework on disease prediction performance and further compares it to different baselines. The framework performance is tested on two large datasets with diverse underlying data, ABIDE and ADNI, for the prediction of Autism Spectrum Disorder and conversion to Alzheimer’s disease, respectively. Our analysis shows that our novel framework can improve over state-of-the-art results on both databases, with 70.4% classification accuracy for ABIDE and 80.0% for ADNI.
doi_str_mv	10.1016/j.media.2018.06.001
format	Article
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[Display omitted] Graphs are widely used as a natural framework that captures interactions between individual elements represented as nodes in a graph. In medical applications, specifically, nodes can represent individuals within a potentially large population (patients or healthy controls) accompanied by a set of features, while the graph edges incorporate associations between subjects in an intuitive manner. This representation allows to incorporate the wealth of imaging and non-imaging information as well as individual subject features simultaneously in disease classification tasks. Previous graph-based approaches for supervised or unsupervised learning in the context of disease prediction solely focus on pairwise similarities between subjects, disregarding individual characteristics and features, or rather rely on subject-specific imaging feature vectors and fail to model interactions between them. In this paper, we present a thorough evaluation of a generic framework that leverages both imaging and non-imaging information and can be used for brain analysis in large populations. This framework exploits Graph Convolutional Networks (GCNs) and involves representing populations as a sparse graph, where its nodes are associated with imaging-based feature vectors, while phenotypic information is integrated as edge weights. The extensive evaluation explores the effect of each individual component of this framework on disease prediction performance and further compares it to different baselines. The framework performance is tested on two large datasets with diverse underlying data, ABIDE and ADNI, for the prediction of Autism Spectrum Disorder and conversion to Alzheimer’s disease, respectively. 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[Display omitted] Graphs are widely used as a natural framework that captures interactions between individual elements represented as nodes in a graph. In medical applications, specifically, nodes can represent individuals within a potentially large population (patients or healthy controls) accompanied by a set of features, while the graph edges incorporate associations between subjects in an intuitive manner. This representation allows to incorporate the wealth of imaging and non-imaging information as well as individual subject features simultaneously in disease classification tasks. Previous graph-based approaches for supervised or unsupervised learning in the context of disease prediction solely focus on pairwise similarities between subjects, disregarding individual characteristics and features, or rather rely on subject-specific imaging feature vectors and fail to model interactions between them. 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[Display omitted] Graphs are widely used as a natural framework that captures interactions between individual elements represented as nodes in a graph. In medical applications, specifically, nodes can represent individuals within a potentially large population (patients or healthy controls) accompanied by a set of features, while the graph edges incorporate associations between subjects in an intuitive manner. This representation allows to incorporate the wealth of imaging and non-imaging information as well as individual subject features simultaneously in disease classification tasks. Previous graph-based approaches for supervised or unsupervised learning in the context of disease prediction solely focus on pairwise similarities between subjects, disregarding individual characteristics and features, or rather rely on subject-specific imaging feature vectors and fail to model interactions between them. In this paper, we present a thorough evaluation of a generic framework that leverages both imaging and non-imaging information and can be used for brain analysis in large populations. This framework exploits Graph Convolutional Networks (GCNs) and involves representing populations as a sparse graph, where its nodes are associated with imaging-based feature vectors, while phenotypic information is integrated as edge weights. The extensive evaluation explores the effect of each individual component of this framework on disease prediction performance and further compares it to different baselines. The framework performance is tested on two large datasets with diverse underlying data, ABIDE and ADNI, for the prediction of Autism Spectrum Disorder and conversion to Alzheimer’s disease, respectively. 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subjects	Algorithms Alzheimer Disease - diagnostic imaging Alzheimer's disease Artificial neural networks Autism Autism Spectrum Disorder Autism Spectrum Disorder - diagnostic imaging Brain Classification Convolutional codes Data processing Databases, Factual Evaluation Graph convolutional networks Graph theory Graphical representations Graphs Humans Medical imaging Neural Networks (Computer) Neuroimaging Neuroimaging - methods Nodes Populations Predictive Value of Tests Semi-supervised classification Spectral theory
title	Disease prediction using graph convolutional networks: Application to Autism Spectrum Disorder and Alzheimer’s disease
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