Improved Deep Thermal Rehabilitation System with Temperature Measurement Function Using Ultrasound Images

Y. Shindo, Kenji Takahashi, F. Ikuta, Y. Iseki, Kazuo Kato
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引用次数: 5

Abstract

This paper describes an improved deep thermal osteoarthritis (OA) rehabilitation system which has a temperature distribution measurement system. In a previous study, we developed a resonant cavity applicator for treating OA and proved that this system was able to heat the knee joint more effectively than other methods; however, this heating system did not have a temperature measurement function. Meanwhile, in a different study, we developed a method using ultrasound imaging techniques to calculate temperature distributions inside the human body. In consideration of clinical application of this applicator, it is necessary to be able to measure the temperature of human tissue during heating. With our applicator, the most important thing is to create an electromagnetic resonant mode deep inside the cavity. Unfortunately, because of electromagnetic interference, we could not utilize an ultrasound imaging probe inside the cavity during heating. To overcome this critical problem, we developed a heating system with a new temperature measurement system. We designed an original jig made of PTFE and developed the remote controllable robotic arm to properly position the probe to take ultrasound images as precisely as possible. Furthermore, the resonant cavity applicator was modified so that it was able to house the ultrasound imaging probe during the heating treatment. In this paper, we first evaluate the performance of the jig by comparing displacement vector distributions. Second, we discuss the results of a heating experiment using this prototype applicator. From our results, it was found that our thermal rehabilitation system with the added temperature measurement function would be useful in clinics for treating osteoarthritis inside the knee joint.
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具有超声图像测温功能的改进型深度热康复系统
本文介绍了一种改进型深热性骨关节炎(OA)康复系统,该系统具有温度分布测量系统。在之前的研究中,我们开发了一种用于治疗OA的谐振腔应用器,并证明该系统能够比其他方法更有效地加热膝关节;然而,这个加热系统没有温度测量功能。与此同时,在另一项研究中,我们开发了一种使用超声成像技术计算人体内温度分布的方法。考虑到该涂抹器的临床应用,需要能够在加热过程中测量人体组织的温度。使用我们的涂敷器,最重要的是在腔内深处创建一个电磁谐振模式。不幸的是,由于电磁干扰,我们无法在加热时在腔内使用超声成像探头。为了克服这一关键问题,我们开发了一种带有新型温度测量系统的加热系统。设计了一种由聚四氟乙烯制成的原始夹具,并开发了遥控机械臂,以正确定位探头,尽可能精确地拍摄超声图像。此外,对谐振腔涂抹器进行了改进,使其能够在加热过程中容纳超声成像探头。在本文中,我们首先通过比较位移矢量分布来评估跳汰机的性能。其次,我们讨论了使用该原型涂敷器进行加热实验的结果。结果表明,我们的热康复系统具有额外的温度测量功能,可用于临床治疗膝关节内骨关节炎。
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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