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Main Authors: Chen, Tao, Zhang, Dan, Chen, Da, Fu, Huazhu, Jin, Kai, Wang, Shanshan, Cohen, Laurent D., Zhao, Yitian, Yi, Quanyong, Zhang, Jiong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.03197
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author Chen, Tao
Zhang, Dan
Chen, Da
Fu, Huazhu
Jin, Kai
Wang, Shanshan
Cohen, Laurent D.
Zhao, Yitian
Yi, Quanyong
Zhang, Jiong
author_facet Chen, Tao
Zhang, Dan
Chen, Da
Fu, Huazhu
Jin, Kai
Wang, Shanshan
Cohen, Laurent D.
Zhao, Yitian
Yi, Quanyong
Zhang, Jiong
contents Choroidal neovascularization (CNV), a primary characteristic of wet age-related macular degeneration (wet AMD), represents a leading cause of blindness worldwide. In clinical practice, optical coherence tomography angiography (OCTA) is commonly used for studying CNV-related pathological changes, due to its micron-level resolution and non-invasive nature. Thus, accurate segmentation of CNV regions and vessels in OCTA images is crucial for clinical assessment of wet AMD. However, challenges existed due to irregular CNV shapes and imaging limitations like projection artifacts, noises and boundary blurring. Moreover, the lack of publicly available datasets constraints the CNV analysis. To address these challenges, this paper constructs the first publicly accessible CNV dataset (CNVSeg), and proposes a novel multilateral graph convolutional interaction-enhanced CNV segmentation network (MTG-Net). This network integrates both region and vessel morphological information, exploring semantic and geometric duality constraints within the graph domain. Specifically, MTG-Net consists of a multi-task framework and two graph-based cross-task modules: Multilateral Interaction Graph Reasoning (MIGR) and Multilateral Reinforcement Graph Reasoning (MRGR). The multi-task framework encodes rich geometric features of lesion shapes and surfaces, decoupling the image into three task-specific feature maps. MIGR and MRGR iteratively reason about higher-order relationships across tasks through a graph mechanism, enabling complementary optimization for task-specific objectives. Additionally, an uncertainty-weighted loss is proposed to mitigate the impact of artifacts and noise on segmentation accuracy. Experimental results demonstrate that MTG-Net outperforms existing methods, achieving a Dice socre of 87.21\% for region segmentation and 88.12\% for vessel segmentation.
format Preprint
id arxiv_https___arxiv_org_abs_2508_03197
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Neovascularization Segmentation via a Multilateral Interaction-Enhanced Graph Convolutional Network
Chen, Tao
Zhang, Dan
Chen, Da
Fu, Huazhu
Jin, Kai
Wang, Shanshan
Cohen, Laurent D.
Zhao, Yitian
Yi, Quanyong
Zhang, Jiong
Computer Vision and Pattern Recognition
Choroidal neovascularization (CNV), a primary characteristic of wet age-related macular degeneration (wet AMD), represents a leading cause of blindness worldwide. In clinical practice, optical coherence tomography angiography (OCTA) is commonly used for studying CNV-related pathological changes, due to its micron-level resolution and non-invasive nature. Thus, accurate segmentation of CNV regions and vessels in OCTA images is crucial for clinical assessment of wet AMD. However, challenges existed due to irregular CNV shapes and imaging limitations like projection artifacts, noises and boundary blurring. Moreover, the lack of publicly available datasets constraints the CNV analysis. To address these challenges, this paper constructs the first publicly accessible CNV dataset (CNVSeg), and proposes a novel multilateral graph convolutional interaction-enhanced CNV segmentation network (MTG-Net). This network integrates both region and vessel morphological information, exploring semantic and geometric duality constraints within the graph domain. Specifically, MTG-Net consists of a multi-task framework and two graph-based cross-task modules: Multilateral Interaction Graph Reasoning (MIGR) and Multilateral Reinforcement Graph Reasoning (MRGR). The multi-task framework encodes rich geometric features of lesion shapes and surfaces, decoupling the image into three task-specific feature maps. MIGR and MRGR iteratively reason about higher-order relationships across tasks through a graph mechanism, enabling complementary optimization for task-specific objectives. Additionally, an uncertainty-weighted loss is proposed to mitigate the impact of artifacts and noise on segmentation accuracy. Experimental results demonstrate that MTG-Net outperforms existing methods, achieving a Dice socre of 87.21\% for region segmentation and 88.12\% for vessel segmentation.
title Neovascularization Segmentation via a Multilateral Interaction-Enhanced Graph Convolutional Network
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2508.03197