Development of Coaxial Needle Applicator Made of Shape Memory Alloy
Y. Shindo, Kazutoshi Shibafuji, Y. Iseki, Kazuo Kato, Hideaki Takahashi, T. Uzuka, A. Takeuchi
{"title":"Development of Coaxial Needle Applicator Made of Shape Memory Alloy","authors":"Y. Shindo, Kazutoshi Shibafuji, Y. Iseki, Kazuo Kato, Hideaki Takahashi, T. Uzuka, A. Takeuchi","doi":"10.3191/THERMALMED.30.27","DOIUrl":null,"url":null,"abstract":"This paper describes a new heating method using a developed coaxial needle applicator made of a shape memory alloy(SMA)to avoid undesirable hotspots and to provide a larger heating area. The radio frequency(RF)interstitial hyperthermia treatment has a direct local heating area around the needle. However,because this heating method uses a discoid electrode on the body surface,the RF current flows between the needle applicator and the discoid electrode. The RF current that flows between the electrodes is known to damage healthy nerves and tissues. To overcome this problem,a new heating method using a coaxial needle applicator was developed. This applicator consists of an inside electrode and an outside electrode, and the discoid electrode is not needed. Moreover, to expand the heating region, an SMA was used as the material for both electrodes. In this paper, we estimated the electromagnetic field around the needle applicator by finite element method (FEM) and performed experiments with the agar phantom using the proposed coaxial needle applicator made of the SMA. First,the structure of the developed SMA coaxial needle applicator is presented. Second,the estimated results with the developed coaxial needle applicator are compared with the results of the straight needle using the discoid electrode. After comparing computer simulation results,the experimental results from both of the applicators are discussed. Furthermore as an example, simulate the treatment of brain tumors;calculated results from the 3D anatomical human head model reconstructed from 2D medical images were discussed. Finally, the experimental results from the SMA coaxial expandable needle applicator and the LeVeen needle,which is used in clinics now,are compared. From these results,it was concluded that the developed SMA coaxial needle applicator is capable of heating a larger region without damaging healthy tissues and nerves. Coaxial needle applicator made of SMA・Y.Shindo et al. ― ― 27 Received 28 March,2014,Accepted 4 June,2014. Corresponding author;Tel,+81-44-934-7355;Fax,+81-44-934-7907; e-mail,yshindo@isc.meiji.ac.jp doi:10.3191/thermalmed.30.27 ©2014 Japanese Society for Thermal Medicine","PeriodicalId":23299,"journal":{"name":"Thermal Medicine","volume":"48 1","pages":"27-40"},"PeriodicalIF":0.0000,"publicationDate":"2014-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Thermal Medicine","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3191/THERMALMED.30.27","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 2
Abstract
This paper describes a new heating method using a developed coaxial needle applicator made of a shape memory alloy(SMA)to avoid undesirable hotspots and to provide a larger heating area. The radio frequency(RF)interstitial hyperthermia treatment has a direct local heating area around the needle. However,because this heating method uses a discoid electrode on the body surface,the RF current flows between the needle applicator and the discoid electrode. The RF current that flows between the electrodes is known to damage healthy nerves and tissues. To overcome this problem,a new heating method using a coaxial needle applicator was developed. This applicator consists of an inside electrode and an outside electrode, and the discoid electrode is not needed. Moreover, to expand the heating region, an SMA was used as the material for both electrodes. In this paper, we estimated the electromagnetic field around the needle applicator by finite element method (FEM) and performed experiments with the agar phantom using the proposed coaxial needle applicator made of the SMA. First,the structure of the developed SMA coaxial needle applicator is presented. Second,the estimated results with the developed coaxial needle applicator are compared with the results of the straight needle using the discoid electrode. After comparing computer simulation results,the experimental results from both of the applicators are discussed. Furthermore as an example, simulate the treatment of brain tumors;calculated results from the 3D anatomical human head model reconstructed from 2D medical images were discussed. Finally, the experimental results from the SMA coaxial expandable needle applicator and the LeVeen needle,which is used in clinics now,are compared. From these results,it was concluded that the developed SMA coaxial needle applicator is capable of heating a larger region without damaging healthy tissues and nerves. Coaxial needle applicator made of SMA・Y.Shindo et al. ― ― 27 Received 28 March,2014,Accepted 4 June,2014. Corresponding author;Tel,+81-44-934-7355;Fax,+81-44-934-7907; e-mail,yshindo@isc.meiji.ac.jp doi:10.3191/thermalmed.30.27 ©2014 Japanese Society for Thermal Medicine
形状记忆合金同轴涂针器的研制
本文介绍了一种新的加热方法,使用一种由形状记忆合金(SMA)制成的同轴针涂抹器,以避免不良的热点,并提供更大的加热面积。射频间质热疗在针头周围有一个直接的局部加热区域。然而,由于这种加热方法在体表上使用一个盘状电极,射频电流在针敷器和盘状电极之间流动。在电极之间流动的射频电流已知会损害健康的神经和组织。为了克服这一问题,开发了一种新的同轴针式加热方法。该涂敷器由一个内电极和一个外电极组成,不需要圆盘电极。此外,为了扩大加热区域,两个电极都使用了SMA作为材料。本文采用有限元法对插针器周围的电磁场进行了估算,并利用SMA制成的同轴插针器进行了琼脂体实验。首先,介绍了研制的SMA同轴施针器的结构。其次,将所开发的同轴针涂抹器的估计结果与使用圆盘电极的直针的结果进行了比较。在比较了计算机模拟结果的基础上,讨论了两种涂布器的实验结果。以模拟脑肿瘤的治疗为例,讨论了由二维医学图像重建的三维解剖人头模型的计算结果。最后,比较了SMA同轴可扩针器与目前临床使用的LeVeen针的实验结果。由此得出结论,所开发的SMA同轴针刺器能够在不损害健康组织和神经的情况下加热更大的区域。同轴施针器由SMA·Y制成。Shindo et al. 2014年3月28日收稿,2014年6月4日收稿。通讯作者,电话+ 81-44-934-7355,传真+ 81-44-934-7907;e-mail,yshindo@isc.meiji.ac.jp doi:10.3191/thermalmed.30.27©2014日本热医学学会
本文章由计算机程序翻译,如有差异,请以英文原文为准。