Deep Learning in Alzheimer's disease: Diagnostic Classification and Prognostic Prediction using Neuroimaging Data
Taeho Jo, Kwangsik Nho, Andrew J. Saykin

TL;DR
This paper reviews recent deep learning methods applied to neuroimaging data for Alzheimer's disease diagnosis and prognosis, highlighting the highest accuracy results and the evolution towards multimodal and explainable models.
Contribution
It systematically reviews and classifies deep learning approaches for AD diagnosis and prediction, emphasizing hybrid models and multimodal data integration.
Findings
Deep learning models achieve up to 98.8% accuracy in AD classification.
Hybrid models combining traditional machine learning and deep learning improve performance.
Multimodal neuroimaging and fluid biomarkers enhance diagnostic accuracy.
Abstract
Deep learning has shown outstanding performance in identifying intricate structures in complex high-dimensional data, especially in the domain of computer vision. The application of deep learning to early detection and automated classification of Alzheimer's disease (AD) has recently gained considerable attention, as rapid progress in neuroimaging techniques has generated large-scale multimodal neuroimaging data. A systematic review of publications using deep learning approaches and neuroimaging data for diagnostic classification of AD was performed. A PubMed and Google Scholar search was used to identify deep learning papers on AD published between January 2013 and July 2018. These papers were reviewed, evaluated, and classified by algorithm and neuroimaging type, and the findings were summarized. Of 16 studies meeting full inclusion criteria, 4 used a combination of deep learning and…
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Taxonomy
TopicsDementia and Cognitive Impairment Research
