Saved in:
Bibliographic Details
Main Authors: Liu, Wentao, Xu, Weijin, Li, Xiaochuan, Liang, Bowen, He, Ziyang, Zhu, Mengke, Song, Jingzhou, Yang, Huihua, Lu, Qingsheng
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.05748
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916632265228288
author Liu, Wentao
Xu, Weijin
Li, Xiaochuan
Liang, Bowen
He, Ziyang
Zhu, Mengke
Song, Jingzhou
Yang, Huihua
Lu, Qingsheng
author_facet Liu, Wentao
Xu, Weijin
Li, Xiaochuan
Liang, Bowen
He, Ziyang
Zhu, Mengke
Song, Jingzhou
Yang, Huihua
Lu, Qingsheng
contents Autonomous robots for endovascular interventions hold significant potential to enhance procedural safety and reliability by navigating guidewires with precision, minimizing human error, and reducing surgical time. However, existing methods of guidewire navigation rely on manual demonstration data and have a suboptimal success rate. In this work, we propose a knowledge-driven visual guidance (KVG) method that leverages available visual information from interventional imaging to facilitate guidewire navigation. Our approach integrates image segmentation and detection techniques to extract surgical knowledge, including vascular maps and guidewire positions. We introduce BDA-star, a novel path planning algorithm with boundary distance constraints, to optimize trajectory planning for guidewire navigation. To validate the method, we developed the KVD-Reinforcement Learning environment, where observations consist of real-time guidewire feeding images highlighting the guidewire tip position and the planned path. We proposed a reward function based on the distances from both the guidewire tip to the planned path and the target to evaluate the agent's actions.Additionally, to address stability issues and slow convergence rates associated with direct learning from raw pixels, we incorporated a pre-trained convolutional neural network into the policy network for feature extraction. Experiments conducted on the aortic simulation autonomous guidewire navigation platform demonstrated that the proposed method, targeting the left subclavian artery, left carotid artery and the brachiocephalic artery, achieved a 100\% guidewire navigation success rate, along with reduced movement and retraction distances and trajectories tend to the center of the vessels.
format Preprint
id arxiv_https___arxiv_org_abs_2403_05748
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Autonomous Guidewire Navigation for Robot-assisted Endovascular Interventions: A Knowledge-Driven Visual Guidance Approach
Liu, Wentao
Xu, Weijin
Li, Xiaochuan
Liang, Bowen
He, Ziyang
Zhu, Mengke
Song, Jingzhou
Yang, Huihua
Lu, Qingsheng
Robotics
Autonomous robots for endovascular interventions hold significant potential to enhance procedural safety and reliability by navigating guidewires with precision, minimizing human error, and reducing surgical time. However, existing methods of guidewire navigation rely on manual demonstration data and have a suboptimal success rate. In this work, we propose a knowledge-driven visual guidance (KVG) method that leverages available visual information from interventional imaging to facilitate guidewire navigation. Our approach integrates image segmentation and detection techniques to extract surgical knowledge, including vascular maps and guidewire positions. We introduce BDA-star, a novel path planning algorithm with boundary distance constraints, to optimize trajectory planning for guidewire navigation. To validate the method, we developed the KVD-Reinforcement Learning environment, where observations consist of real-time guidewire feeding images highlighting the guidewire tip position and the planned path. We proposed a reward function based on the distances from both the guidewire tip to the planned path and the target to evaluate the agent's actions.Additionally, to address stability issues and slow convergence rates associated with direct learning from raw pixels, we incorporated a pre-trained convolutional neural network into the policy network for feature extraction. Experiments conducted on the aortic simulation autonomous guidewire navigation platform demonstrated that the proposed method, targeting the left subclavian artery, left carotid artery and the brachiocephalic artery, achieved a 100\% guidewire navigation success rate, along with reduced movement and retraction distances and trajectories tend to the center of the vessels.
title Autonomous Guidewire Navigation for Robot-assisted Endovascular Interventions: A Knowledge-Driven Visual Guidance Approach
topic Robotics
url https://arxiv.org/abs/2403.05748