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Main Authors: Liu, Zixuan, Honjaya, Aaron, Xu, Yuekai, Zhang, Yi, Pan, Hefu, Wang, Xin, Shapiro, Linda G, Wang, Sheng, Wang, Ruikang K
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.05991
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author Liu, Zixuan
Honjaya, Aaron
Xu, Yuekai
Zhang, Yi
Pan, Hefu
Wang, Xin
Shapiro, Linda G
Wang, Sheng
Wang, Ruikang K
author_facet Liu, Zixuan
Honjaya, Aaron
Xu, Yuekai
Zhang, Yi
Pan, Hefu
Wang, Xin
Shapiro, Linda G
Wang, Sheng
Wang, Ruikang K
contents Retinal vessel segmentation is critical for diagnosing ocular conditions, yet current deep learning methods are limited by modality-specific challenges and significant distribution shifts across imaging devices, resolutions, and anatomical regions. In this paper, we propose GrInAdapt, a novel framework for source-free multi-target domain adaptation that leverages multi-view images to refine segmentation labels and enhance model generalizability for optical coherence tomography angiography (OCTA) of the fundus of the eye. GrInAdapt follows an intuitive three-step approach: (i) grounding images to a common anchor space via registration, (ii) integrating predictions from multiple views to achieve improved label consensus, and (iii) adapting the source model to diverse target domains. Furthermore, GrInAdapt is flexible enough to incorporate auxiliary modalities such as color fundus photography, to provide complementary cues for robust vessel segmentation. Extensive experiments on a multi-device, multi-site, and multi-modal retinal dataset demonstrate that GrInAdapt significantly outperforms existing domain adaptation methods, achieving higher segmentation accuracy and robustness across multiple domains. These results highlight the potential of GrInAdapt to advance automated retinal vessel analysis and support robust clinical decision-making.
format Preprint
id arxiv_https___arxiv_org_abs_2503_05991
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle GrInAdapt: Scaling Retinal Vessel Structural Map Segmentation Through Grounding, Integrating and Adapting Multi-device, Multi-site, and Multi-modal Fundus Domains
Liu, Zixuan
Honjaya, Aaron
Xu, Yuekai
Zhang, Yi
Pan, Hefu
Wang, Xin
Shapiro, Linda G
Wang, Sheng
Wang, Ruikang K
Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
Retinal vessel segmentation is critical for diagnosing ocular conditions, yet current deep learning methods are limited by modality-specific challenges and significant distribution shifts across imaging devices, resolutions, and anatomical regions. In this paper, we propose GrInAdapt, a novel framework for source-free multi-target domain adaptation that leverages multi-view images to refine segmentation labels and enhance model generalizability for optical coherence tomography angiography (OCTA) of the fundus of the eye. GrInAdapt follows an intuitive three-step approach: (i) grounding images to a common anchor space via registration, (ii) integrating predictions from multiple views to achieve improved label consensus, and (iii) adapting the source model to diverse target domains. Furthermore, GrInAdapt is flexible enough to incorporate auxiliary modalities such as color fundus photography, to provide complementary cues for robust vessel segmentation. Extensive experiments on a multi-device, multi-site, and multi-modal retinal dataset demonstrate that GrInAdapt significantly outperforms existing domain adaptation methods, achieving higher segmentation accuracy and robustness across multiple domains. These results highlight the potential of GrInAdapt to advance automated retinal vessel analysis and support robust clinical decision-making.
title GrInAdapt: Scaling Retinal Vessel Structural Map Segmentation Through Grounding, Integrating and Adapting Multi-device, Multi-site, and Multi-modal Fundus Domains
topic Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2503.05991