Computational Design of a Thermal Applicator for Brain Hyperthermia Controlled by Capacitor Positioning in Loop Coils.

IF 3.2 Magnetic resonance in medical sciences : MRMS : an official journal of Japan Society of Magnetic Resonance in Medicine Pub Date : 2025-10-24 Epub Date: 2025-01-23 DOI:10.2463/mrms.mp.2024-0086

Daniel Hernandez, Taewoo Nam, Eunwoo Lee, Yeunchul Ryu, Jun-Young Chung, Kyoung-Nam Kim

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Abstract

Purpose: Hyperthermia is a treatment that applies heat to damage or kill cancer cells and can be also used for drug deliveries. It is important to apply the heat into the specific area in order to target the cancer tissue and avoid damaging healthy tissue. For this reason, the development of heat applicators that have the capability to deliver the heat to the target area is vital. In this study, we present an optimization of an array coil for brain hyperthermia that can be used in combination with MRI, such that the heat can be delivered to the cancer area.

Methods: The array coils were based on optimizing loop coils by varying the capacitor's position along the perimeter. The optimization was performed using electromagnetic simulations, by computing the electric field (E) and temperature inside of the brain and targeting tumor tissues for focus temperature application. The coils were compared with a general-use symmetric coil array for head heating.

Results: The optimization of the coil array was able to focus electric field and make temperature rise at the cancer areas. The temperature in Tumor 1 before and after standard and the proposed method optimization was 43.6°C, 48.3°C, and 42.5°C and for Tumor 2 the temperatures were 44.2°C, 43.1°C, and 42.9°C, respectively. Although the standard optimization method exhibits higher temperatures, it also had higher temperatures outside the tumors area.

Conclusion: We demonstrated the optimization of array coils with different capacitor positions to obtain focused heating temperatures.

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回路线圈电容定位控制脑热疗器的计算设计。

目的：热疗是一种通过加热来破坏或杀死癌细胞的治疗方法，也可用于药物输送。重要的是要将热量应用到特定的区域，以针对癌症组织，避免损害健康组织。出于这个原因，开发能够将热量传递到目标区域的热应用器是至关重要的。在这项研究中，我们提出了一种可以与MRI结合使用的脑热疗阵列线圈的优化，这样热量就可以传递到癌症区域。方法：通过改变电容器沿圆周的位置来优化环形线圈。通过电磁模拟，通过计算大脑内部的电场(E)和温度，并针对肿瘤组织进行聚焦温度应用，进行了优化。将该线圈与用于头部加热的通用对称线圈阵列进行了比较。结果：优化后的线圈阵列能够聚焦电场，使癌变部位温度升高。肿瘤1标准前后的温度为43.6°C, 48.3°C, 42.5°C，肿瘤2标准前后的温度为44.2°C, 43.1°C, 42.9°C。虽然标准优化方法具有较高的温度，但它在肿瘤区域外也具有较高的温度。结论：优化了不同电容位置的阵列线圈，获得了集中的加热温度。

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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Magnetic resonance in medical sciences : MRMS : an official journal of Japan Society of Magnetic Resonance in Medicine

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