Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression

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Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression Publisher Pubmed

S Aghajanian SEPEHR ; F Mohammadifard FATEME ; I Mohammadi IDA ; S Rajai Firouzabadi SHAHRYAR ; A Baradaran Bagheri ALI ; Em Ghaffary Elham MOASES ; O Mirmosayyeb OMID

Source: Alzheimer's Research and Therapy Published:2025

Abstract

Background: Alzheimer’s disease (AD) is the principal cause of dementia and requires the early diagnosis of people with mild cognitive impairment (MCI) who are at high risk of progressing. Early diagnosis is imperative for optimizing clinical management and selecting proper therapeutic interventions. Structural magnetic resonance imaging (MRI) markers have been widely investigated for predicting the conversion of MCI to AD, and recent advances in deep learning (DL) methods offer enhanced capabilities for identifying subtle neurodegenerative changes over time. Methods: We selected 228 MCI participants from the Alzheimer’s Disease Neuroimaging Initiative (ADNI) who had at least three T1-weighted MRI scans within 18 months of baseline. MRI volumes underwent bias correction, segmentation, and radiomics feature extraction. A 3D residual network (ResNet3D) was trained using a pairwise ranking loss to capture single-timepoint risk scores. Longitudinal analyses were performed by extracting deep convolutional neural network (CNN) embeddings and gray matter radiomics for each scan, which were put into a time-aware long short-term memory (LSTM) model with an attention mechanism. Results: A single-timepoint ResNet3D model achieved modest performance (c-index ~ 0.70). Incorporating longitudinal MRI files or downstream survival models led to a pronounced prognostic improvement (c-index:0.80–0.90), but was not further improved by longitudinal radiomics data. Time-specific classification within two- and three-year and five-year windows after the last MRI acquisition showed high accuracy (AUC > 0.85). Several radiomics, including gray matter surface to volume and elongation, emerged as the most predictive features. Each SD change in the gray matter surface to volume change within the last visit was associated with an increased risk of developing AD (HR: 1.50; 95% CI: 1.25–1.79). Conclusions: These findings emphasize the value of structural MRI within the advanced DL architectures for predicting MCI-to-AD conversion. The approach may enable earlier risk stratification and targeted interventions for individuals most likely to progress. limitations in sample size and computational resources warrant larger, more diverse studies to confirm these observations and explore additional improvements. © 2025 Elsevier B.V., All rights reserved.

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Style	Citing Format
MLA	S Aghajanian SEPEHR, et al.. "Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression." Alzheimer's Research and Therapy, vol. 17, no. 1, 2025, pp. -.
APA	S Aghajanian SEPEHR, F Mohammadifard FATEME, I Mohammadi IDA, S Rajai Firouzabadi SHAHRYAR, A Baradaran Bagheri ALI, Em Ghaffary Elham MOASES, O Mirmosayyeb OMID (2025). Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression. Alzheimer's Research and Therapy, 17(1), -.
Chicago	S Aghajanian SEPEHR, F Mohammadifard FATEME, I Mohammadi IDA, S Rajai Firouzabadi SHAHRYAR, A Baradaran Bagheri ALI, Em Ghaffary Elham MOASES, O Mirmosayyeb OMID. "Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression." Alzheimer's Research and Therapy 17, no. 1 (2025): -.
Harvard	S Aghajanian SEPEHR et al. (2025) 'Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression', Alzheimer's Research and Therapy, 17(1), pp. -.
Vancouver	S Aghajanian SEPEHR, F Mohammadifard FATEME, I Mohammadi IDA, S Rajai Firouzabadi SHAHRYAR, A Baradaran Bagheri ALI, Em Ghaffary Elham MOASES, et al.. Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression. Alzheimer's Research and Therapy. 2025;17(1):-.
BibTex	@article{ author = {S Aghajanian SEPEHR and F Mohammadifard FATEME and I Mohammadi IDA and S Rajai Firouzabadi SHAHRYAR and A Baradaran Bagheri ALI and Em Ghaffary Elham MOASES and O Mirmosayyeb OMID}, title = {Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression}, journal = {Alzheimer's Research and Therapy}, volume = {17}, number = {1}, pages = {-}, year = {2025} }
RIS	TY - JOUR AU - S Aghajanian SEPEHR AU - F Mohammadifard FATEME AU - I Mohammadi IDA AU - S Rajai Firouzabadi SHAHRYAR AU - A Baradaran Bagheri ALI AU - Em Ghaffary Elham MOASES AU - O Mirmosayyeb OMID TI - Longitudinal Structural Mri-Based Deep Learning and Radiomics Features for Predicting Alzheimer’S Disease Progression JO - Alzheimer's Research and Therapy VL - 17 IS - 1 SP - EP - PY - 2025 ER -

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