VasGuideNet: Vascular Topology-Guided Couinaud Liver Segmentation with Structural Contrastive Loss
- URL: http://arxiv.org/abs/2602.21539v1
- Date: Wed, 25 Feb 2026 03:50:48 GMT
- Title: VasGuideNet: Vascular Topology-Guided Couinaud Liver Segmentation with Structural Contrastive Loss
- Authors: Chaojie Shen, Jingjun Gu, Zihao Zhao, Ruocheng Li, Cunyuan Yang, Jiajun Bu, Lei Wu,
- Abstract summary: We propose VasGuideNet, the first Couinaud segmentation framework explicitly guided by vascular topology.<n>VasGuideNet achieves Dice scores of 83.68% and 76.65% with RVDs of 1.68 and 7.08.<n>It consistently outperforms representative baselines including UNETR, Swin UNETR, and G-UNETR++.
- Score: 15.54612173358869
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Accurate Couinaud liver segmentation is critical for preoperative surgical planning and tumor localization.However, existing methods primarily rely on image intensity and spatial location cues, without explicitly modeling vascular topology. As a result, they often produce indistinct boundaries near vessels and show limited generalization under anatomical variability.We propose VasGuideNet, the first Couinaud segmentation framework explicitly guided by vascular topology. Specifically, skeletonized vessels, Euclidean distance transform (EDT)--derived geometry, and k-nearest neighbor (kNN) connectivity are encoded into topology features using Graph Convolutional Networks (GCNs). These features are then injected into a 3D encoder--decoder backbone via a cross-attention fusion module. To further improve inter-class separability and anatomical consistency, we introduce a Structural Contrastive Loss (SCL) with a global memory bank.On Task08_HepaticVessel and our private LASSD dataset, VasGuideNet achieves Dice scores of 83.68% and 76.65% with RVDs of 1.68 and 7.08, respectively. It consistently outperforms representative baselines including UNETR, Swin UNETR, and G-UNETR++, delivering higher Dice/mIoU and lower RVD across datasets, demonstrating its effectiveness for anatomically consistent segmentation. Code is available at https://github.com/Qacket/VasGuideNet.git.
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