English

Optical flow-based vascular respiratory motion compensation

Robotics 2023-09-01 v1

Abstract

This paper develops a new vascular respiratory motion compensation algorithm, Motion-Related Compensation (MRC), to conduct vascular respiratory motion compensation by extrapolating the correlation between invisible vascular and visible non-vascular. Robot-assisted vascular intervention can significantly reduce the radiation exposure of surgeons. In robot-assisted image-guided intervention, blood vessels are constantly moving/deforming due to respiration, and they are invisible in the X-ray images unless contrast agents are injected. The vascular respiratory motion compensation technique predicts 2D vascular roadmaps in live X-ray images. When blood vessels are visible after contrast agents injection, vascular respiratory motion compensation is conducted based on the sparse Lucas-Kanade feature tracker. An MRC model is trained to learn the correlation between vascular and non-vascular motions. During the intervention, the invisible blood vessels are predicted with visible tissues and the trained MRC model. Moreover, a Gaussian-based outlier filter is adopted for refinement. Experiments on in-vivo data sets show that the proposed method can yield vascular respiratory motion compensation in 0.032 sec, with an average error 1.086 mm. Our real-time and accurate vascular respiratory motion compensation approach contributes to modern vascular intervention and surgical robots.

Keywords

Cite

@article{arxiv.2308.16451,
  title  = {Optical flow-based vascular respiratory motion compensation},
  author = {Keke Yang and Zheng Zhang and Meng Li and Tuoyu Cao and Maani Ghaffari and Jingwei Song},
  journal= {arXiv preprint arXiv:2308.16451},
  year   = {2023}
}

Comments

This manuscript has been accepted by IEEE Robotics and Automation Letters

R2 v1 2026-06-28T12:08:59.373Z