Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations

Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations

Combining machine learning with neuroimaging data has a great potential for early diagnosis of mild cognitive impairment (MCI) and Alzheimer's disease (AD). However, it remains unclear how well the classifiers built on one population can predict MCI/AD diagnosis of other populations. This study...

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Main Authors: Chong-Yaw Wee, Chaoqiang Liu, Annie Lee, Joann S. Poh, Hui Ji, Anqi Qiu
Format: Article
Language:English
Published: Elsevier 2019-01-01
Series:NeuroImage: Clinical
Online Access:http://www.sciencedirect.com/science/article/pii/S2213158219302797
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spelling doaj-c786607a728a4174ad55b94c275efee72020-11-25T01:18:41ZengElsevierNeuroImage: Clinical2213-15822019-01-0123Cortical graph neural network for AD and MCI diagnosis and transfer learning across populationsChong-Yaw Wee0Chaoqiang Liu1Annie Lee2Joann S. Poh3Hui Ji4Anqi Qiu5Department of Biomedical Engineering and Clinical Research Center, National University of Singapore, SingaporeDepartment of Biomedical Engineering and Clinical Research Center, National University of Singapore, SingaporeDepartment of Biomedical Engineering and Clinical Research Center, National University of Singapore, SingaporeDepartment of Biomedical Engineering and Clinical Research Center, National University of Singapore, SingaporeDepartment of Mathematics, National University of Singapore, SingaporeDepartment of Biomedical Engineering and Clinical Research Center, National University of Singapore, Singapore; Corresponding author at: Department of Biomedical Engineering, National University of Singapore, 4 Engineering Drive 3, Block E4 #04-08, 117583, Singapore.Combining machine learning with neuroimaging data has a great potential for early diagnosis of mild cognitive impairment (MCI) and Alzheimer's disease (AD). However, it remains unclear how well the classifiers built on one population can predict MCI/AD diagnosis of other populations. This study aimed to employ a spectral graph convolutional neural network (graph-CNN), that incorporated cortical thickness and geometry, to identify MCI and AD based on 3089 T1-weighted MRI data of the ADNI-2 cohort, and to evaluate its feasibility to predict AD in the ADNI-1 cohort (n = 3602) and an Asian cohort (n = 347). For the ADNI-2 cohort, the graph-CNN showed classification accuracy of controls (CN) vs. AD at 85.8% and early MCI (EMCI) vs. AD at 79.2%, followed by CN vs. late MCI (LMCI) (69.3%), LMCI vs. AD (65.2%), EMCI vs. LMCI (60.9%), and CN vs. EMCI (51.8%). We demonstrated the robustness of the graph-CNN among the existing deep learning approaches, such as Euclidean-domain-based multilayer network and 1D CNN on cortical thickness, and 2D and 3D CNNs on T1-weighted MR images of the ADNI-2 cohort. The graph-CNN also achieved the prediction on the conversion of EMCI to AD at 75% and that of LMCI to AD at 92%. The find-tuned graph-CNN further provided a promising CN vs. AD classification accuracy of 89.4% on the ADNI-1 cohort and >90% on the Asian cohort. Our study demonstrated the feasibility to transfer AD/MCI classifiers learned from one population to the other. Notably, incorporating cortical geometry in CNN has the potential to improve classification performance. Keywords: Dementia classification, Cortical thickness, Graph, Convolutional neural networks, Transfer learninghttp://www.sciencedirect.com/science/article/pii/S2213158219302797
collection DOAJ
language English
format Article
sources DOAJ
author Chong-Yaw Wee
Chaoqiang Liu
Annie Lee
Joann S. Poh
Hui Ji
Anqi Qiu
spellingShingle Chong-Yaw Wee
Chaoqiang Liu
Annie Lee
Joann S. Poh
Hui Ji
Anqi Qiu
Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
NeuroImage: Clinical
author_facet Chong-Yaw Wee
Chaoqiang Liu
Annie Lee
Joann S. Poh
Hui Ji
Anqi Qiu
author_sort Chong-Yaw Wee
title Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
title_short Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
title_full Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
title_fullStr Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
title_full_unstemmed Cortical graph neural network for AD and MCI diagnosis and transfer learning across populations
title_sort cortical graph neural network for ad and mci diagnosis and transfer learning across populations
publisher Elsevier
series NeuroImage: Clinical
issn 2213-1582
publishDate 2019-01-01
description Combining machine learning with neuroimaging data has a great potential for early diagnosis of mild cognitive impairment (MCI) and Alzheimer's disease (AD). However, it remains unclear how well the classifiers built on one population can predict MCI/AD diagnosis of other populations. This study aimed to employ a spectral graph convolutional neural network (graph-CNN), that incorporated cortical thickness and geometry, to identify MCI and AD based on 3089 T1-weighted MRI data of the ADNI-2 cohort, and to evaluate its feasibility to predict AD in the ADNI-1 cohort (n = 3602) and an Asian cohort (n = 347). For the ADNI-2 cohort, the graph-CNN showed classification accuracy of controls (CN) vs. AD at 85.8% and early MCI (EMCI) vs. AD at 79.2%, followed by CN vs. late MCI (LMCI) (69.3%), LMCI vs. AD (65.2%), EMCI vs. LMCI (60.9%), and CN vs. EMCI (51.8%). We demonstrated the robustness of the graph-CNN among the existing deep learning approaches, such as Euclidean-domain-based multilayer network and 1D CNN on cortical thickness, and 2D and 3D CNNs on T1-weighted MR images of the ADNI-2 cohort. The graph-CNN also achieved the prediction on the conversion of EMCI to AD at 75% and that of LMCI to AD at 92%. The find-tuned graph-CNN further provided a promising CN vs. AD classification accuracy of 89.4% on the ADNI-1 cohort and >90% on the Asian cohort. Our study demonstrated the feasibility to transfer AD/MCI classifiers learned from one population to the other. Notably, incorporating cortical geometry in CNN has the potential to improve classification performance. Keywords: Dementia classification, Cortical thickness, Graph, Convolutional neural networks, Transfer learning
url http://www.sciencedirect.com/science/article/pii/S2213158219302797
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