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Auteurs principaux: Chen, Rusi, Yang, Yuanting, Yao, Jiezhi, Song, Hongning, Zhang, Ji, Zhou, Yongsong, Huang, Yuhao, Yang, Ronghao, Jia, Dan, Zhang, Yuhan, Tao, Xing, Dou, Haoran, Zhou, Qing, Yang, Xin, Ni, Dong
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.00660
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author Chen, Rusi
Yang, Yuanting
Yao, Jiezhi
Song, Hongning
Zhang, Ji
Zhou, Yongsong
Huang, Yuhao
Yang, Ronghao
Jia, Dan
Zhang, Yuhan
Tao, Xing
Dou, Haoran
Zhou, Qing
Yang, Xin
Ni, Dong
author_facet Chen, Rusi
Yang, Yuanting
Yao, Jiezhi
Song, Hongning
Zhang, Ji
Zhou, Yongsong
Huang, Yuhao
Yang, Ronghao
Jia, Dan
Zhang, Yuhan
Tao, Xing
Dou, Haoran
Zhou, Qing
Yang, Xin
Ni, Dong
contents Mitral regurgitation is one of the most prevalent cardiac disorders. Four-dimensional (4D) ultrasound has emerged as the primary imaging modality for assessing dynamic valvular morphology. However, 4D mitral valve (MV) analysis remains challenging due to limited phase annotations, severe motion artifacts, and poor imaging quality. Yet, the absence of inter-phase dependency in existing methods hinders 4D MV analysis. To bridge this gap, we propose a Motion-Topology guided consistency network (MTCNet) for accurate 4D MV ultrasound segmentation in semi-supervised learning (SSL). MTCNet requires only sparse end-diastolic and end-systolic annotations. First, we design a cross-phase motion-guided consistency learning strategy, utilizing a bi-directional attention memory bank to propagate spatio-temporal features. This enables MTCNet to achieve excellent performance both per- and inter-phase. Second, we devise a novel topology-guided correlation regularization that explores physical prior knowledge to maintain anatomically plausible. Therefore, MTCNet can effectively leverage structural correspondence between labeled and unlabeled phases. Extensive evaluations on the first largest 4D MV dataset, with 1408 phases from 160 patients, show that MTCNet performs superior cross-phase consistency compared to other advanced methods (Dice: 87.30%, HD: 1.75mm). Both the code and the dataset are available at https://github.com/crs524/MTCNet.
format Preprint
id arxiv_https___arxiv_org_abs_2507_00660
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MTCNet: Motion and Topology Consistency Guided Learning for Mitral Valve Segmentationin 4D Ultrasound
Chen, Rusi
Yang, Yuanting
Yao, Jiezhi
Song, Hongning
Zhang, Ji
Zhou, Yongsong
Huang, Yuhao
Yang, Ronghao
Jia, Dan
Zhang, Yuhan
Tao, Xing
Dou, Haoran
Zhou, Qing
Yang, Xin
Ni, Dong
Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Mitral regurgitation is one of the most prevalent cardiac disorders. Four-dimensional (4D) ultrasound has emerged as the primary imaging modality for assessing dynamic valvular morphology. However, 4D mitral valve (MV) analysis remains challenging due to limited phase annotations, severe motion artifacts, and poor imaging quality. Yet, the absence of inter-phase dependency in existing methods hinders 4D MV analysis. To bridge this gap, we propose a Motion-Topology guided consistency network (MTCNet) for accurate 4D MV ultrasound segmentation in semi-supervised learning (SSL). MTCNet requires only sparse end-diastolic and end-systolic annotations. First, we design a cross-phase motion-guided consistency learning strategy, utilizing a bi-directional attention memory bank to propagate spatio-temporal features. This enables MTCNet to achieve excellent performance both per- and inter-phase. Second, we devise a novel topology-guided correlation regularization that explores physical prior knowledge to maintain anatomically plausible. Therefore, MTCNet can effectively leverage structural correspondence between labeled and unlabeled phases. Extensive evaluations on the first largest 4D MV dataset, with 1408 phases from 160 patients, show that MTCNet performs superior cross-phase consistency compared to other advanced methods (Dice: 87.30%, HD: 1.75mm). Both the code and the dataset are available at https://github.com/crs524/MTCNet.
title MTCNet: Motion and Topology Consistency Guided Learning for Mitral Valve Segmentationin 4D Ultrasound
topic Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2507.00660