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Main Authors: Hamid, Nur Amirah Abd, Rusli, Mohd Shahrizal, Taufek, Muhammad Thaqif Iman Mohd, Shapiai, Mohd Ibrahim, Lai, Daphne Teck Ching
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.17619
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author Hamid, Nur Amirah Abd
Rusli, Mohd Shahrizal
Taufek, Muhammad Thaqif Iman Mohd
Shapiai, Mohd Ibrahim
Lai, Daphne Teck Ching
author_facet Hamid, Nur Amirah Abd
Rusli, Mohd Shahrizal
Taufek, Muhammad Thaqif Iman Mohd
Shapiai, Mohd Ibrahim
Lai, Daphne Teck Ching
contents Accurate prediction of clinical scores is critical for early detection and prognosis of Alzheimers disease (AD). While existing approaches primarily focus on forecasting the ADAS-Cog global score, they often overlook the predictive value of its sub-scores (13 items), which capture domain-specific cognitive decline. In this study, we propose a multi task learning (MTL) framework that jointly predicts the global ADAS-Cog score and its sub-scores (13 items) at Month 24 using baseline MRI and longitudinal clinical scores from baseline and Month 6. The main goal is to examine how each sub scores particularly those associated with MRI features contribute to the prediction of the global score, an aspect largely neglected in prior MTL studies. We employ Vision Transformer (ViT) and Swin Transformer architectures to extract imaging features, which are fused with longitudinal clinical inputs to model cognitive progression. Our results show that incorporating sub-score learning improves global score prediction. Subscore level analysis reveals that a small subset especially Q1 (Word Recall), Q4 (Delayed Recall), and Q8 (Word Recognition) consistently dominates the predicted global score. However, some of these influential sub-scores exhibit high prediction errors, pointing to model instability. Further analysis suggests that this is caused by clinical feature dominance, where the model prioritizes easily predictable clinical scores over more complex MRI derived features. These findings emphasize the need for improved multimodal fusion and adaptive loss weighting to achieve more balanced learning. Our study demonstrates the value of sub score informed modeling and provides insights into building more interpretable and clinically robust AD prediction frameworks. (Github repo provided)
format Preprint
id arxiv_https___arxiv_org_abs_2508_17619
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Improving Interpretability in Alzheimer's Prediction via Joint Learning of ADAS-Cog Scores
Hamid, Nur Amirah Abd
Rusli, Mohd Shahrizal
Taufek, Muhammad Thaqif Iman Mohd
Shapiai, Mohd Ibrahim
Lai, Daphne Teck Ching
Computer Vision and Pattern Recognition
Accurate prediction of clinical scores is critical for early detection and prognosis of Alzheimers disease (AD). While existing approaches primarily focus on forecasting the ADAS-Cog global score, they often overlook the predictive value of its sub-scores (13 items), which capture domain-specific cognitive decline. In this study, we propose a multi task learning (MTL) framework that jointly predicts the global ADAS-Cog score and its sub-scores (13 items) at Month 24 using baseline MRI and longitudinal clinical scores from baseline and Month 6. The main goal is to examine how each sub scores particularly those associated with MRI features contribute to the prediction of the global score, an aspect largely neglected in prior MTL studies. We employ Vision Transformer (ViT) and Swin Transformer architectures to extract imaging features, which are fused with longitudinal clinical inputs to model cognitive progression. Our results show that incorporating sub-score learning improves global score prediction. Subscore level analysis reveals that a small subset especially Q1 (Word Recall), Q4 (Delayed Recall), and Q8 (Word Recognition) consistently dominates the predicted global score. However, some of these influential sub-scores exhibit high prediction errors, pointing to model instability. Further analysis suggests that this is caused by clinical feature dominance, where the model prioritizes easily predictable clinical scores over more complex MRI derived features. These findings emphasize the need for improved multimodal fusion and adaptive loss weighting to achieve more balanced learning. Our study demonstrates the value of sub score informed modeling and provides insights into building more interpretable and clinically robust AD prediction frameworks. (Github repo provided)
title Improving Interpretability in Alzheimer's Prediction via Joint Learning of ADAS-Cog Scores
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2508.17619