Abstract
PurposePlanning a safe path for flexible catheters is one of the major challenges of endovascular catheterization. State-of-the-art methods rarely consider the catheter curvature constraint and reduced computational time of path planning which guarantees the possibility to re-plan the path during the actual operation. MethodsIn this manuscript, we propose a fast two-phase path planning approach under the robot curvature constraint. Firstly, the vascular structure is extracted and represented by vascular centerlines and corresponding vascular radii. Then, the path is searched along the vascular centerline using breadth first search (BFS) strategy and locally optimized via the genetic algorithm (GA) to satisfy the robot curvature constraint. This approach (BFS-GA) is able to respect the robot curvature constraint while keeping it close to the centerlines as much as possible. We can also reduce the optimization search space and perform parallel optimization to shorten the computational time. ResultsWe demonstrate the method’s high efficiency in two-dimensional and three-dimensional space scenarios. The results showed the planner’s ability to satisfy the robot curvature constraint while keeping low computational time cost compared with sampling-based methods. Path replanning in femoral arteries can reach an updating frequency at 6.4pm 2.3Hz. ConclusionThe presented work is suited for surgical procedures demanding satisfying curvature constraints while optimizing specified criteria. It is also applicable for curvature constrained robots in narrow passages.
Highlights
Percutaneous coronary intervention (PCI) is used to widen stenotic and occluded blood vessels by pushing the plaque aside and placing a stent nearby to restore and maintain the blood circulation
Sampling-based methods such as extended probabilistic roadmap [8] and bidirectional rapidly exploring random tree (Bi-RRT) [5] are able to plan the path in configuration space
The breadth first search (BFS) strategy starts at the tree root and explores the k-nearest neighbor centerline nodes at the present depth prior to moving on to the nodes at the depth level
Summary
We demonstrate the method’s high efficiency in two-dimensional and three-dimensional space scenarios. The results showed the planner’s ability to satisfy the robot curvature constraint while keeping low computational time cost compared with sampling-based methods. Path replanning in femoral arteries can reach an updating frequency at 6.4 ± 2.3Hz. Conclusion The presented work is suited for surgical procedures demanding satisfying curvature constraints while optimizing specified criteria. Conclusion The presented work is suited for surgical procedures demanding satisfying curvature constraints while optimizing specified criteria It is applicable for curvature constrained robots in narrow passages. Keywords Path planning · Flexible catheter · Autonomous endovascular intervention · Curvature constraints · Robotic surgery
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