arxiv_cv 95% Match Research Paper Medical Imaging Researchers,Radiologists,Medical Physicists,AI Researchers in Healthcare 2 weeks ago

X$^{2}$-Gaussian: 4D Radiative Gaussian Splatting for Continuous-time Tomographic Reconstruction

computer-vision › medical-imaging

📄 Abstract

Abstract: Four-dimensional computed tomography (4D CT) reconstruction is crucial for capturing dynamic anatomical changes but faces inherent limitations from conventional phase-binning workflows. Current methods discretize temporal resolution into fixed phases with respiratory gating devices, introducing motion misalignment and restricting clinical practicality. In this paper, We propose X$^2$-Gaussian, a novel framework that enables continuous-time 4D-CT reconstruction by integrating dynamic radiative Gaussian splatting with self-supervised respiratory motion learning. Our approach models anatomical dynamics through a spatiotemporal encoder-decoder architecture that predicts time-varying Gaussian deformations, eliminating phase discretization. To remove dependency on external gating devices, we introduce a physiology-driven periodic consistency loss that learns patient-specific breathing cycles directly from projections via differentiable optimization. Extensive experiments demonstrate state-of-the-art performance, achieving a 9.93 dB PSNR gain over traditional methods and 2.25 dB improvement against prior Gaussian splatting techniques. By unifying continuous motion modeling with hardware-free period learning, X$^2$-Gaussian advances high-fidelity 4D CT reconstruction for dynamic clinical imaging. Code is publicly available at: https://x2-gaussian.github.io/.

Authors (6)

Weihao Yu

Yuanhao Cai

Ruyi Zha

Zhiwen Fan

Chenxin Li

Yixuan Yuan

Submitted

March 27, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

Proposes X$^2$-Gaussian, a novel framework for continuous-time 4D CT reconstruction by integrating dynamic radiative Gaussian splatting with self-supervised respiratory motion learning. It eliminates phase discretization and removes dependency on external gating devices by learning breathing cycles directly from projections.

Business Value

Improved 4D CT reconstruction can lead to more accurate diagnosis and treatment planning for dynamic diseases (e.g., lung cancer), potentially reducing radiation exposure and improving patient outcomes.

Paper Metadata

Innovation Type

Novel Method/Framework

Deployment Feasibility

Moderate. Requires integration into CT scanner acquisition protocols and image reconstruction pipelines. Validation with clinical data and regulatory approval are necessary.

Limitations Addressed

Addresses the limitations of conventional 4D CT reconstruction methods, such as motion misalignment and restricted clinical practicality caused by fixed phase binning and reliance on external gating devices.

Performance Gains

Enables continuous-time reconstruction, eliminating phase discretization and improving motion modeling accuracy compared to traditional phase-binned 4D CT.

Technical Tags

4D CT reconstructioncontinuous-timeGaussian splattingradiance fieldsrespiratory motionself-supervised learningdifferentiable optimizationdynamic tomographymedical imaging

Research Topics

Medical Imaging Reconstruction4D Computed Tomography (4D CT)Dynamic ModelingRadiative FieldsSelf-Supervised Learning

Methods & Architectures

X$^2$-Gaussian frameworkDynamic Radiative Gaussian SplattingSelf-supervised Respiratory Motion LearningSpatiotemporal Encoder-Decoder ArchitecturePhysiology-driven Periodic Consistency LossDifferentiable Optimization Spatiotemporal Encoder-Decoder ArchitectureGaussian Splatting (adapted for dynamic scenes)

Applications & Tasks

Medical Imaging Radiology Healthcare Limitations of phase-binning in 4D CTMotion misalignment and restricted clinical practicalityDependency on external gating devicesDiscretization of temporal resolution Continuous-time 4D CT reconstructionAccurate modeling of dynamic anatomical changesReducing motion artifacts in CT scans

Related Fields

Medical ImagingComputer VisionRadiologyTomographyDeep LearningGenerative ModelsSignal Processing

Keywords

4D CTContinuous-time ReconstructionGaussian SplattingMedical ImagingRadiologyRespiratory MotionSelf-supervised LearningDynamic TomographyDeep LearningMotion Artifacts

Academic Context

#Medical Imaging Reconstruction#4D Computed Tomography (4D CT)#Dynamic Modeling#Radiative Fields#Self-Supervised Learning

Technology Stack

Frameworks & Libraries

PyTorch (likely)

Commercial Potential

Potential Products

Advanced 4D CT reconstruction softwareAI-powered diagnostic tools for dynamic imagingSystems for real-time motion compensation in medical imaging

Target Industries

HealthcareMedical Device ManufacturingRadiology ServicesPharmaceuticals (for clinical trials)

Use Case Examples

Generating high-resolution, continuous-time 4D CT scans for precise tumor tracking during radiation therapy planningImproving the visualization of dynamic anatomical structures for diagnosisReducing motion artifacts in lung CT scans without requiring patient breath-holds

Competitive Edge

Offers a continuous-time reconstruction approach using Gaussian splatting and self-supervised motion learning, overcoming the limitations of discrete phase-binning and external gating devices in conventional 4D CT.

Market Opportunity

Significant market for advanced medical imaging and diagnostic solutions.

Revenue Models

Licensing to medical imaging equipment manufacturersintegration into PACS/RIS systemsspecialized reconstruction services.

Resource Requirements

Compute Needs

Likely high, requiring significant computational resources for training and potentially for reconstruction, depending on the implementation.

Data Requirements

Requires 4D CT datasets (projection data and potentially reconstructed volumes) with synchronized motion information or derived physiological signals.

Deployment Constraints

Requires integration into existing medical imaging workflows and hardware. Clinical validation and regulatory approval are essential. Computational time for reconstruction needs to be clinically acceptable.

Scalability

Scalability depends on the efficiency of the Gaussian splatting and motion modeling components.

Regulatory Considerations

Highas it involves medical diagnostic imaging and treatment planning (e.g.FDACE marking).

Production Readiness

Maturity Level

Research

Time to Market

3-5 years, due to extensive clinical validation and regulatory processes.

Patent Potential

High, related to the novel framework combining Gaussian splatting with self-supervised motion learning for continuous-time 4D CT.

View Full Paper Back to Papers