Saved in:
Bibliographic Details
Main Authors: Inigo, Blanca, Killeen, Benjamin D., Choi, Rebecca, Song, Michelle, Uneri, Ali, Khan, Majid, Bailey, Christopher, Krieger, Axel, Unberath, Mathias
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.05803
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915656856764416
author Inigo, Blanca
Killeen, Benjamin D.
Choi, Rebecca
Song, Michelle
Uneri, Ali
Khan, Majid
Bailey, Christopher
Krieger, Axel
Unberath, Mathias
author_facet Inigo, Blanca
Killeen, Benjamin D.
Choi, Rebecca
Song, Michelle
Uneri, Ali
Khan, Majid
Bailey, Christopher
Krieger, Axel
Unberath, Mathias
contents Robotic systems are transforming image-guided interventions by enhancing accuracy and minimizing radiation exposure. A significant challenge in robotic assistance lies in surgical path planning, which often relies on the registration of intraoperative 2D images with preoperative 3D CT scans. This requirement can be burdensome and costly, particularly in procedures like vertebroplasty, where preoperative CT scans are not routinely performed. To address this issue, we introduce a differentiable rendering-based framework for 3D transpedicular path planning utilizing bi-planar 2D X-rays. Our method integrates differentiable rendering with a vertebral atlas generated through a Statistical Shape Model (SSM) and employs a learned similarity loss to refine the SSM shape and pose dynamically, independent of fixed imaging geometries. We evaluated our framework in two stages: first, through vertebral reconstruction from orthogonal X-rays for benchmarking, and second, via clinician-in-the-loop path planning using arbitrary-view X-rays. Our results indicate that our method outperformed a normalized cross-correlation baseline in reconstruction metrics (DICE: 0.75 vs. 0.65) and achieved comparable performance to the state-of-the-art model ReVerteR (DICE: 0.77), while maintaining generalization to arbitrary views. Success rates for bipedicular planning reached 82% with synthetic data and 75% with cadaver data, exceeding the 66% and 31% rates of a 2D-to-3D baseline, respectively. In conclusion, our framework facilitates versatile, CT-free 3D path planning for robot-assisted vertebroplasty, effectively accommodating real-world imaging diversity without the need for preoperative CT scans.
format Preprint
id arxiv_https___arxiv_org_abs_2512_05803
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle 3D Path Planning for Robot-assisted Vertebroplasty from Arbitrary Bi-plane X-ray via Differentiable Rendering
Inigo, Blanca
Killeen, Benjamin D.
Choi, Rebecca
Song, Michelle
Uneri, Ali
Khan, Majid
Bailey, Christopher
Krieger, Axel
Unberath, Mathias
Robotics
Artificial Intelligence
Robotic systems are transforming image-guided interventions by enhancing accuracy and minimizing radiation exposure. A significant challenge in robotic assistance lies in surgical path planning, which often relies on the registration of intraoperative 2D images with preoperative 3D CT scans. This requirement can be burdensome and costly, particularly in procedures like vertebroplasty, where preoperative CT scans are not routinely performed. To address this issue, we introduce a differentiable rendering-based framework for 3D transpedicular path planning utilizing bi-planar 2D X-rays. Our method integrates differentiable rendering with a vertebral atlas generated through a Statistical Shape Model (SSM) and employs a learned similarity loss to refine the SSM shape and pose dynamically, independent of fixed imaging geometries. We evaluated our framework in two stages: first, through vertebral reconstruction from orthogonal X-rays for benchmarking, and second, via clinician-in-the-loop path planning using arbitrary-view X-rays. Our results indicate that our method outperformed a normalized cross-correlation baseline in reconstruction metrics (DICE: 0.75 vs. 0.65) and achieved comparable performance to the state-of-the-art model ReVerteR (DICE: 0.77), while maintaining generalization to arbitrary views. Success rates for bipedicular planning reached 82% with synthetic data and 75% with cadaver data, exceeding the 66% and 31% rates of a 2D-to-3D baseline, respectively. In conclusion, our framework facilitates versatile, CT-free 3D path planning for robot-assisted vertebroplasty, effectively accommodating real-world imaging diversity without the need for preoperative CT scans.
title 3D Path Planning for Robot-assisted Vertebroplasty from Arbitrary Bi-plane X-ray via Differentiable Rendering
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2512.05803