Saved in:
Bibliographic Details
Main Authors: Wang, Xinkun, Wang, Yifang, Liang, Senwei, Tang, Feilong, Liu, Chengzhi, Hu, Ming, Hu, Chao, He, Junjun, Ge, Zongyuan, Razzak, Imran
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.05319
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909659559886848
author Wang, Xinkun
Wang, Yifang
Liang, Senwei
Tang, Feilong
Liu, Chengzhi
Hu, Ming
Hu, Chao
He, Junjun
Ge, Zongyuan
Razzak, Imran
author_facet Wang, Xinkun
Wang, Yifang
Liang, Senwei
Tang, Feilong
Liu, Chengzhi
Hu, Ming
Hu, Chao
He, Junjun
Ge, Zongyuan
Razzak, Imran
contents This paper discusses how ophthalmologists often rely on multimodal data to improve diagnostic accuracy. However, complete multimodal data is rare in real-world applications due to a lack of medical equipment and concerns about data privacy. Traditional deep learning methods typically address these issues by learning representations in latent space. However, the paper highlights two key limitations of these approaches: (i) Task-irrelevant redundant information (e.g., numerous slices) in complex modalities leads to significant redundancy in latent space representations. (ii) Overlapping multimodal representations make it difficult to extract unique features for each modality. To overcome these challenges, the authors propose the Essence-Point and Disentangle Representation Learning (EDRL) strategy, which integrates a self-distillation mechanism into an end-to-end framework to enhance feature selection and disentanglement for more robust multimodal learning. Specifically, the Essence-Point Representation Learning module selects discriminative features that improve disease grading performance. The Disentangled Representation Learning module separates multimodal data into modality-common and modality-unique representations, reducing feature entanglement and enhancing both robustness and interpretability in ophthalmic disease diagnosis. Experiments on multimodal ophthalmology datasets show that the proposed EDRL strategy significantly outperforms current state-of-the-art methods.
format Preprint
id arxiv_https___arxiv_org_abs_2503_05319
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Robust Multimodal Learning for Ophthalmic Disease Grading via Disentangled Representation
Wang, Xinkun
Wang, Yifang
Liang, Senwei
Tang, Feilong
Liu, Chengzhi
Hu, Ming
Hu, Chao
He, Junjun
Ge, Zongyuan
Razzak, Imran
Computer Vision and Pattern Recognition
Artificial Intelligence
This paper discusses how ophthalmologists often rely on multimodal data to improve diagnostic accuracy. However, complete multimodal data is rare in real-world applications due to a lack of medical equipment and concerns about data privacy. Traditional deep learning methods typically address these issues by learning representations in latent space. However, the paper highlights two key limitations of these approaches: (i) Task-irrelevant redundant information (e.g., numerous slices) in complex modalities leads to significant redundancy in latent space representations. (ii) Overlapping multimodal representations make it difficult to extract unique features for each modality. To overcome these challenges, the authors propose the Essence-Point and Disentangle Representation Learning (EDRL) strategy, which integrates a self-distillation mechanism into an end-to-end framework to enhance feature selection and disentanglement for more robust multimodal learning. Specifically, the Essence-Point Representation Learning module selects discriminative features that improve disease grading performance. The Disentangled Representation Learning module separates multimodal data into modality-common and modality-unique representations, reducing feature entanglement and enhancing both robustness and interpretability in ophthalmic disease diagnosis. Experiments on multimodal ophthalmology datasets show that the proposed EDRL strategy significantly outperforms current state-of-the-art methods.
title Robust Multimodal Learning for Ophthalmic Disease Grading via Disentangled Representation
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2503.05319