DeGenseGS: Geometrically and Semantically Decoupled Surgical Scene Understanding in 4D Gaussian Splatting
2026-07-06 • Computer Vision and Pattern Recognition
Computer Vision and Pattern Recognition
AI summaryⓘ
The authors present DeGenseGS, a new method to improve 4D surgical scene understanding by separately handling how meaning (semantics) and shape (geometry) change over time. Their design uses a special module to sync semantic changes with motion without mixing them up with geometric shifts. They also introduce techniques to better extract and preserve semantic details, reducing errors in 3D reconstructions. Tests show their approach better matches semantic labels to actual anatomy even when tissues move or change shape a lot.
4D reconstructionsemantic segmentationgeometry deformationVision-Language ModelsGaussian SplattingHexPlanerasterizationspatiotemporal modelinglatent spacesurgical scene understanding
Authors
Yimo Wang, Bin Kang, Shuojue Yang, Yueming Jin
Abstract
Real-time, text-promptable 4D reconstruction is indispensable for autonomous surgical interaction. Severe misalignment between semantic meaning and physical anatomy still persists, largely because existing solutions integrate Vision-Language Models into deformable fields via a rigid coupling scheme that tightly binds semantic features to geometric warping. In this paper, we propose DeGenseGS, Geometrically and Semantically Decoupled Surgical Scene Understanding in 4D Gaussian Splatting, a novel framework that independently models semantic evolution and geometric deformation. Specifically, we propose a HexPlane-based spatiotemporal entanglement module that uses shared kinematic latents to synchronize semantic mutations with scene dynamics, while explicitly disentangling semantic updates from geometric deformation. To further ensure robustness against reconstruction artifacts, we devise a Rasterization-Native Semantic Extraction mechanism that infers semantics from topologically continuous feature maps. Additionally, we incorporate an angular-aligned optimization strategy that conforms to the native hyperspherical latent space, thereby preventing semantic distortion. Extensive evaluations on the CholecSeg8k and EndoVis18 datasets demonstrate that DeGenseGS achieves state-of-the-art performance. Our framework yields enhanced geometric completeness and robust semantic-anatomic alignment, enabling spatially continuous segmentation despite drastic tissue deformation and topological transitions.