X-Splat:基于高斯泼溅的从单张全景X光片生成三维CBCT影像 / X-Splat: Gaussian Splatting for 3D CBCT Generation from Single Panoramic Radiograph
1️⃣ 一句话总结
本文提出X-Splat方法,首次利用高斯泼溅技术,从单张牙齿全景X光片中生成高质量的三维锥形束CT影像,克服了传统方法无法清晰重建牙齿边界和下颌神经管等精细结构的难题。
Generating a 3D dental volume from a single panoramic radiograph (PXR) could provide a low-radiation alternative to Cone-Beam Computed Tomography (CBCT), but the problem is highly underdetermined: panoramic acquisition integrates 3D attenuation along curved X-ray paths into a 2D image, leaving depth-resolved anatomy unobserved. Existing implicit and generative approaches often produce oversmoothed geometry or anatomically inconsistent hallucinations, lacking geometry-driven supervision and relying on smooth representations unable to precisely localize sharp anatomical boundaries. We propose X-Splat, the first Gaussian Splatting framework for generating CBCT-like 3D dental volumes from a single PXR. X-Splat uses the known panoramic acquisition geometry as a generation scaffold: learnable anisotropic Gaussian primitives are initialized along the X-ray paths that formed the input image and adjusted in a single feed-forward pass, constrained by Beer-Lambert reprojection and multi-view radiographic training supervision. A lightweight residual refiner adds dataset-level anatomical priors without overriding the geometry already resolved by the Gaussians. We train on synthetic PXR-CBCT pairs, enabling direct volumetric supervision without paired real scans. We further introduce segmentation-based geometry-aware metrics, providing the first evaluation of PXR-based generation over maxillofacial anatomy. X-Splat outperforms NeRF- and GAN-based baselines, recovering individual teeth, cortical boundaries, and alveolar structure, including the mandibular canal which prior methods fail to reconstruct. Code will be available at this https URL
X-Splat:基于高斯泼溅的从单张全景X光片生成三维CBCT影像 / X-Splat: Gaussian Splatting for 3D CBCT Generation from Single Panoramic Radiograph
本文提出X-Splat方法,首次利用高斯泼溅技术,从单张牙齿全景X光片中生成高质量的三维锥形束CT影像,克服了传统方法无法清晰重建牙齿边界和下颌神经管等精细结构的难题。
源自 arXiv: 2607.02099