Multi-task deep learning framework for enhancing Mayo endoscopic score classification in ulcerative colitis

Multi-task deep learning framework for enhancing Mayo endoscopic score classification in ulcerative colitis

Objective Ulcerative colitis (UC) endoscopic image classification presents challenges owing to imbalanced medical imaging data, particularly when the clinical importance of accurate positive predictions increases with disease severity. This study proposes a multi-task learning (MTL) framework inspir...

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Bibliographic Details
Main Authors: Jaehyuk Lee, Eunchan Kim
Format: Article
Language:English
Published: SAGE Publishing 2025-07-01
Series:Digital Health
Online Access:https://doi.org/10.1177/20552076251356396
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Summary:Objective Ulcerative colitis (UC) endoscopic image classification presents challenges owing to imbalanced medical imaging data, particularly when the clinical importance of accurate positive predictions increases with disease severity. This study proposes a multi-task learning (MTL) framework inspired by the coarse-to-fine processing mechanism of the human brain to address these challenges. Methods The proposed MTL framework was evaluated using endoscopic images of UC, focusing on its ability to classify disease stages with an emphasis on the accurate detection of advanced cases. Results Our findings demonstrate that the proposed framework effectively mitigates the limitations posed by imbalanced datasets, particularly by enhancing classification performance in severe disease stages. Notably, DenseNet121 exhibited significantly superior performance compared to other backbones and achieved an additional performance gain in identifying Mayo endoscopic scores of 2 and 3 following joint-loss optimization. Additionally, MobileNet-v3-large, despite being a lightweight model, demonstrated notable gains under the proposed optimization scheme, highlighting the versatility of the framework across architectures with different computational complexities. Conclusion MTL-based computer-aided diagnosis enables conservative and accurate identification of patients in critical stages, supporting timely and appropriate treatment decisions while reducing the risk of underdiagnosis and delayed care. Furthermore, our results highlight the potential of MTL in overcoming data imbalance issues. Future studies should explore integrating multiple convolutional neural network-based models to further boost classification accuracy.
ISSN:2055-2076

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