Conceptual and simulative study of the transverse electromagnetic (TEM) RF coil as an RF hyperthermia applicator at 9.4 Tesla

2015 Loughborough Antennas & Propagation Conference (LAPC) Pub Date : 2015-11-01 DOI:10.1109/LAPC.2015.7366078

J. Slim, D. Heberling

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引用次数: 1

Abstract

The objective of this publication is to provide a conceptual and simulative study of a multi-channel hybrid coil system used primarily in magnetic resonance (MR) systems for imaging as a heat inducing system for RF hyperthermia applications. A 16-channels transverse electromagnetic (TEM) coil has been designed for dual purposes as a heat inducing device and as a transceiver for magnetic resonance imaging at 400 MHz (equivalent to the protons Larmor frequency at 9.4 Tesla). Full wave and circuit-wave co-simulations have been carried out. The point specific absorption rate (SAR) pattern is computed. The 3dB width of the formed `hotspot' is also evaluated and analyzed. Good matching (-28 dB) has been achieved at 400 MHz. The coupling between adjacent elements was -10.81 dB. The point SAR (with 1 W as accepted power) shows a clear sharp hotspot when the coils are used for heating. The 3dB width of the RF induced hotspot was 38 mm. The TEM RF coil used in high field MRI system, can be used as an RF hyperthermia applicator for simultaneous heating and imaging. The performance of the system shows a clear advantage compared to existing commercial system. No water bolus is required.

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横向电磁(TEM)射频线圈作为9.4特斯拉射频热疗应用器的概念和模拟研究

本出版物的目的是提供多通道混合线圈系统的概念和模拟研究，该系统主要用于磁共振(MR)成像系统，作为射频热疗应用的热诱导系统。一个16通道的横向电磁(TEM)线圈被设计为双重用途，作为一个热感应装置和一个400兆赫的磁共振成像收发器(相当于质子拉莫尔频率在9.4特斯拉)。进行了全波和电路波联合仿真。计算了点比吸收率(SAR)图。还对形成的“热点”的3dB宽度进行了评估和分析。在400 MHz时实现了良好的匹配(-28 dB)。相邻元件之间的耦合为-10.81 dB。当线圈用于加热时，点SAR(接受功率为1w)显示出清晰的尖锐热点。射频诱导热点的3dB宽度为38 mm。用于高场MRI系统的TEM射频线圈，可作为射频热疗应用器，同时加热和成像。与现有的商用系统相比，该系统的性能具有明显的优势。不需要水丸。

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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2015 Loughborough Antennas & Propagation Conference (LAPC)

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