Hybrid position/force control system of the ultrasonic treatment device by parallel-link robot

Kaoru Natsume, S. Irisawa, S. Onogi, T. Mochizuki, K. Masuda
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Abstract

Microbubbles are widely used as contrast agents in ultrasound diagnosis. Microbubbles may also has therapeutic uses in the heat amplification of high-intensity focused ultrasound ablation or as carriers of acoustic targeted drug gene delivery therapy. However, microbubbles injected into a blood vessel are diffused throughout the whole body ; therefore, their efficiency is still limited. If microbubbles could be controlled in vivo, their efficiency and efficacy would be significantly improved. To address this issue, we have proposed a technique that controls microbubble behavior in blood vessels using ultrasound emitted from the body surface. To apply the technique in vivo, robotic ultrasound transducer positioning on body surface is required. For this purpose, we have developed a robotic system and confirmed that microbubble can be manipulated by the system. In more practical condition, focal length of an ultrasound transducer has to be considered. To address the issue, we propose a control system considering the focal length in this study. The system consists of a parallel-link robot for ultrasound transducer positioning, a robot controller, and an optical tracking device. The robot has three arms, and a transducer holder, and a six-axis force sensor. The robot controller generates ultrasound emission plans using body surface position measured by the tracking device, and manipulate the robot. As for validation of the system, we performed following experiments ; 1) positioning accuracy evaluation without contact, 2) evaluation of contact forces control, and 3) in vitro ultrasound emission tests. From the first experiment, positioning accuracy was less than 1 mm. As for the contact force control validation, the system could keep required reaction force for ultrasound emission on a phantom surface within 1.5 mm errors. In the third experiment, the errors in the perpendicular direction of the ultrasound axis and the direction of the axis were 0.71 mm and 5.52 mm, respectively. From the results, we confirmed that the system could emit ultrasound to a target by using a hydrophone in a poly(ethylene glycol) monomethacrylate (PEGMA) phantom. Consequently, the results demonstrated that the proposed system could generate appropriate plan and manipulate an ultrasound transducer on body surface considering contact condition with body surface.
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基于并联机器人的超声处理装置位置/力混合控制系统
微泡在超声诊断中被广泛用作造影剂。微泡也可用于高强度聚焦超声消融的热放大或作为声学靶向药物基因递送治疗的载体。然而,注入血管的微泡会扩散到全身;因此,它们的效率仍然有限。如果能在体内控制微泡,其效率和疗效将得到显著提高。为了解决这个问题,我们提出了一种利用体表发出的超声波来控制血管微泡行为的技术。为了在体内应用该技术,需要在体表定位机器人超声换能器。为此,我们开发了一个机器人系统,并证实了该系统可以操纵微泡。在更实际的情况下,必须考虑超声换能器的焦距。为了解决这个问题,我们提出了一个考虑焦距的控制系统。该系统由用于超声换能器定位的并联机器人、机器人控制器和光学跟踪装置组成。机器人有三个手臂,一个传感器支架和一个六轴力传感器。机器人控制器利用跟踪装置测量的体表位置生成超声波发射图,并对机器人进行操纵。对于系统的验证,我们进行了以下实验;1)无接触定位精度评价,2)接触力控制评价,3)体外超声发射试验。从第一次实验开始,定位精度小于1mm。在接触力控制验证方面,系统可以将超声发射所需的反作用力保持在1.5 mm误差以内。在第三个实验中,超声轴垂直方向和轴向的误差分别为0.71 mm和5.52 mm。从结果中,我们证实了该系统可以通过在聚乙二醇单甲基丙烯酸酯(PEGMA)模体中使用水听器向目标发射超声波。结果表明,该系统可以根据人体与体表的接触情况,在体表上生成合适的规划和操纵超声换能器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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