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Original Article

Korean Journal of Medical Physics 2016; 27(3): 117-124

Published online September 30, 2016

Copyright © Korean Society of Medical Physics.

Feasibility Study of Robotics-based Patient Immobilization Device for Real-time Motion Compensation

Hyekyun Chung*†, Seungryong Cho*, Byungchul Cho

*Department of Nuclear and Quantum Engineering, Korea Advanced Institute of Science and Technology, Daejeon, Department of Radiation Oncology, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea

Received: August 31, 2016; Revised: September 19, 2016; Accepted: September 20, 2016

Abstract

Intrafractional motion of patients, such as respiratory motion during radiation treatment, is an important issue in image-guided radiotherapy. The accuracy of the radiation treatment decreases as the motion range increases. We developed a control system for a robotic patient immobilization system that enables to reduce the range of tumor motion by compensating the tumor motion. Fusion technology, combining robotics and mechatronics, was developed and applied in this study. First, a small-sized prototype was established for use with an industrial miniature robot. The patient immobilization system consisted of an optical tracking system, a robotic couch, a robot controller, and a control program for managing the system components. A multi speed and position control mechanism with three degrees of freedom was designed. The parameters for operating the control system, such as the coordinate transformation parameters and calibration parameters, were measured and evaluated for a prototype device. After developing the control system using the prototype device, a feasibility test on a full-scale patient immobilization system was performed, using a large industrial robot and couch. The performances of both the prototype device and the realistic device were evaluated using a respiratory motion phantom, for several patterns of respiratory motion. For all patterns of motion, the root mean squared error of the corresponding detected motion trajectories were reduced by more than 40%. The proposed system improves the accuracy of the radiation dose delivered to the target and reduces the unwanted irradiation of normal tissue.

KeywordsRobotics, Mechatronics, Patient immobilizer, Respiratory motion, SBRT

Korean Society of Medical Physics

Vol.35 No.3
September 2024

pISSN 2508-4445
eISSN 2508-4453
Formerly ISSN 1226-5829

Frequency: Quarterly

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