3D打印热修复共振腔应用器的温度分布

Y. Iseki, Shunsuke Kurosawa, Y. Shindo, Kazuo Kato
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引用次数: 0

摘要

骨关节炎(OA)是最常见的关节疾病之一。热疗法,如使用微波透热涂抹器,广泛用于OA。为了进行有效的热疗,膝关节深层组织应加热至36°C-38°C。然而,使用微波透热涂抹器加热这个深层区域是具有挑战性的。之前,我们提出了一种谐振腔应用器来克服这些问题,并证实了它的能力(在牛膝盖上的加热实验),可以在没有物理接触的情况下加热膝关节的深层区域。此外,我们还提出了一种利用超声图像测量温度的方法。该方法采用无创图像分析方法测量温度分布。在之前的研究中,我们发现温度测量精度≤1.0°C。在本文中,我们描述了使用3d打印膝盖模型治疗OA的温度分布。首先,我们创建了膝关节的三维有限元模型(FEM)和2D医学图像的3D打印膝关节模型。其次,我们计算了有限元模型中的温度分布,并对加热系统的原型进行了加热实验。第三,我们进行了定位精度实验,以研究我们的温度测量系统的准确性,该系统由机械臂、3d打印膝盖模型和超声诊断组成。最后,我们根据超声图像测量了3d打印膝关节模型内部的温度分布。加热实验证实,该方法可以对膝关节深层区域进行加热,不会产生不良热点。因此,我们的结果表明,该方法可用于OA的有效热疗。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Temperature Distribution of Resonant Cavity Applicator for Thermal Rehabilitation Using 3D Printing
Osteoarthritis (OA) is one of the most common joint diseases. Thermotherapy, such as that using a microwave diathermy applicator, is widely used for OA. The deep tissue of a knee joint should be heated to 36 °C-38 °C for an effective thermotherapy. However, heating this deep region using a microwave diathermy applicator is challenging. Previously, we proposed a resonant cavity applicator to overcome these problems and confirmed its ability (heating experiments on bovine knees) to heat the deep region of a knee joint without physical contact. Furthermore, we proposed a method of temperature measurement using ultrasound images. In this method, the temperature distribution was measured using noninvasive image analysis. In a previous study, we found temperature measurement accuracy of ≤ 1.0 °C. In the present paper, we describe a temperature distribution using a 3D-printed knee model for treating OA. First, we created a 3D finite element model (FEM) of the knee and a 3D-printed knee model from 2D medical images. Second, we calculated temperature distributions in the FEM model and performed a heating experiment with a prototype of the heating system. Third, we performed positioning accuracy experiments to investigate the accuracy of our temperature measurement system comprising a robotic arm, 3D-printed knee model, and ultrasound diagnostics. Finally, we measured the temperature distribution inside the 3D-printed knee model from ultrasound images. The heating experiments confirmed that our proposed method could heat deep regions of a knee joint without any undesirable hotspot. Therefore, our results suggest that this method is useful for effective thermotherapy of OA.
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