A Hybrid Computational Approach for Efficient Alzheimer's Disease Classification Based on Heterogeneous Data

Overview

Journal Sci Rep

Specialty Science

Date 2018 Jun 29

PMID 29950585

Citations 18

Authors

Xuemei Ding

Magda Bucholc

Haiying Wang

David H Glass

Hui Wang

Dave H Clarke

Anthony John Bjourson

Le Roy C Dowey

Maurice OKane

Girijesh Prasad

Liam Maguire

KongFatt Wong-Lin

Affiliations

Soon will be listed here.

Abstract

There is currently a lack of an efficient, objective and systemic approach towards the classification of Alzheimer's disease (AD), due to its complex etiology and pathogenesis. As AD is inherently dynamic, it is also not clear how the relationships among AD indicators vary over time. To address these issues, we propose a hybrid computational approach for AD classification and evaluate it on the heterogeneous longitudinal AIBL dataset. Specifically, using clinical dementia rating as an index of AD severity, the most important indicators (mini-mental state examination, logical memory recall, grey matter and cerebrospinal volumes from MRI and active voxels from PiB-PET brain scans, ApoE, and age) can be automatically identified from parallel data mining algorithms. In this work, Bayesian network modelling across different time points is used to identify and visualize time-varying relationships among the significant features, and importantly, in an efficient way using only coarse-grained data. Crucially, our approach suggests key data features and their appropriate combinations that are relevant for AD severity classification with high accuracy. Overall, our study provides insights into AD developments and demonstrates the potential of our approach in supporting efficient AD diagnosis.

Citing Articles

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