Sensor and Sampling-based motion planning for minimally invasive robotic exploration of osteolytic lesions

Abstract

This paper develops a sensor- and sampling-based motion planner to control a surgical robot in order to explore osteolytic lesions in orthopedic surgery. Because of the difficulty of using conventional surgical tools, such exploration is needed in minimally-invasive treatments of ¿particle diseases,¿ which commonly result from material wear in total hip replacements. Since a geometric model of the osteolytic cavity is not always available, the planner relies only on a robot model that can detect collisions. As such, the planner can work in conjunction with real systems. The planner effectively combines global and local exploration. The global layer determines which regions to explore, while local exploration uses information gain to move the robot tip to positions in the region that increase exploration. Simulation experiments are conducted using a snake-like cannula robot on surgically-relevant osteolytic cavities. As desired in minimally-invasive treatment of osteolysis, performance is measured as the volume explored by the robot tip. The proposed method achieves 83-92% performance rate when compared to methods that require 3D models of osteolytic cavities. Comparisons to sensor-based related work (i.e., no 3D models) show significant improvements in performance.