arxiv_cv 90% Match Research Paper Robotics researchers,Medical imaging specialists,Surgical simulation developers,Computer graphics engineers 2 days ago

SAGS: Self-Adaptive Alias-Free Gaussian Splatting for Dynamic Surgical Endoscopic Reconstruction

computer-vision › 3d-vision

📄 Abstract

Abstract: Surgical reconstruction of dynamic tissues from endoscopic videos is a crucial technology in robot-assisted surgery. The development of Neural Radiance Fields (NeRFs) has greatly advanced deformable tissue reconstruction, achieving high-quality results from video and image sequences. However, reconstructing deformable endoscopic scenes remains challenging due to aliasing and artifacts caused by tissue movement, which can significantly degrade visualization quality. The introduction of 3D Gaussian Splatting (3DGS) has improved reconstruction efficiency by enabling a faster rendering pipeline. Nevertheless, existing 3DGS methods often prioritize rendering speed while neglecting these critical issues. To address these challenges, we propose SAGS, a self-adaptive alias-free Gaussian splatting framework. We introduce an attention-driven, dynamically weighted 4D deformation decoder, leveraging 3D smoothing filters and 2D Mip filters to mitigate artifacts in deformable tissue reconstruction and better capture the fine details of tissue movement. Experimental results on two public benchmarks, EndoNeRF and SCARED, demonstrate that our method achieves superior performance in all metrics of PSNR, SSIM, and LPIPS compared to the state of the art while also delivering better visualization quality.

Authors (7)

Wenfeng Huang

Xiangyun Liao

Yinling Qian

Hao Liu

Yongming Yang

Wenjing Jia

+1 more

Submitted

October 31, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

SAGS proposes a self-adaptive, alias-free Gaussian Splatting framework for dynamic surgical endoscopic reconstruction. It addresses artifacts caused by tissue movement by introducing an attention-driven deformation decoder and adaptive filtering, improving visualization quality while maintaining efficient rendering.

Business Value

Enhances the realism and utility of surgical simulations and robotic-assisted surgery by providing high-quality, artifact-free 3D reconstructions of dynamic tissues, improving training and intraoperative guidance.

Paper Metadata

Innovation Type

Methodological/Algorithmic

Deployment Feasibility

Feasible for research and development, but real-time deployment in operating rooms requires rigorous testing, validation, and integration with surgical systems.

Limitations Addressed

Solves the problem of aliasing and artifacts in reconstructing dynamic, deformable tissues from endoscopic videos, which degrade visualization quality in existing NeRF and 3DGS methods.

Technical Tags

Gaussian Splattingdynamic scenesdeformable tissuesendoscopic reconstructionalias-freeself-adaptiveneural radiance fields (NeRFs)real-time renderingSAGS

Research Topics

3D ReconstructionSurgical SimulationComputer VisionNeural RenderingDeformable Object Tracking

Methods & Architectures

self-adaptive Gaussian splattingattention-driven deformation decoderdynamically weighted3D smoothing filters2D Mip filters 3D Gaussian Splatting (3DGS)Neural Radiance Fields (NeRFs)

Applications & Tasks

Robotic Surgery Medical Simulation Augmented Reality Endoscopy Aliasing and Artifacts in Dynamic ScenesDegradation from Tissue MovementPrioritizing Rendering Speed over QualityReconstruction of Deformable Tissues Dynamic Surgical ReconstructionEndoscopic Video Analysis3D Scene RenderingDeformable Tissue Modeling

Related Fields

Computer Vision3D GraphicsRoboticsMedical TechnologySurgical Simulation

Keywords

Gaussian Splattingdynamic scenesdeformable tissuesendoscopicreconstructionalias-freeNeRF3Dsurgicalreal-time renderingSAGS

Academic Context

#3D Reconstruction#Surgical Simulation#Computer Vision#Neural Rendering#Deformable Object Tracking

Commercial Potential

Potential Products

Surgical simulation softwareReal-time 3D reconstruction module for endoscopyAR visualization tools for surgery

Target Industries

HealthcareMedical DevicesRoboticsSimulation & Training

Use Case Examples

Providing surgeons with a real-time, high-fidelity 3D view of the surgical siteTraining surgeons on complex procedures using realistic simulationsEnabling augmented reality overlays during surgery

Competitive Edge

Improves upon existing 3DGS methods by specifically addressing artifacts in dynamic, deformable scenes, offering higher quality reconstructions for surgical applications.

Market Opportunity

Significant market for surgical simulation and visualization technologies.

Revenue Models

Licensing of technologydevelopment of specialized surgical tools.

Resource Requirements

Compute Needs

High, requires powerful GPUs for training and real-time rendering.

Data Requirements

Requires sequences of endoscopic videos with corresponding camera poses.

Deployment Constraints

Real-time performance in a clinical setting requires optimized hardware and software integration. Handling diverse tissue types and deformations is challenging.

Scalability

Scalability depends on the complexity of the scene and the desired frame rate. Efficient rendering is a key feature.

Regulatory Considerations

Medical device regulationsdata privacy.

Production Readiness

Maturity Level

Research/Prototype

Time to Market

3-5 years (for clinical deployment)

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