Implementation of Time Reversal Focusing on Hyperthermia Treatment of Brain Tumours

2023 Photonics & Electromagnetics Research Symposium (PIERS) Pub Date : 2023-07-03 DOI:10.1109/PIERS59004.2023.10221372

Michaela Černá, T. Drizdal

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Abstract

According to NBTS (National Brain Tumor Society), glioblastoma is the most occurring primary malignant brain tumor [1]. Current research shows the benefit of combining hyperthermia and radiotherapy for these brain tumors. The hyperthermia treatment planning (HTP) is used for treatment guidance. HTP is usually divided into three individual steps: segmentation, electromagnetic (EM) simulations, and phase-amplitude optimization. To find the best phase and amplitude of the antenna element input signals using either specific absorption rate (SAR)-based or temperature-based optimizations. The main advantage of SAR-base optimization is the speed and computational complexity, but these optimizations need to consider the cooling mechanisms of the human body and the water bolus. Currently, several methods for SAR-based optimization like particle swarm optimization (PSO), Nelder-Mead simplex algorithm (NMS), genetic algorithm (GA), or Time reversal focusing (TRF) have been introduced. Time reversal focusing consists of forward and reverse steps. First, the virtual EM source is placed in the tumor. According to [2], it is not a suitable source directly to the center; better results are achieved if the source is near the surface of the tumor. Next, a wavefront is propagated from a virtually located source, recorded by peripheral antenna elements. These signals are time reversed for detection amplitude and phase. In the second step, these values are set, and the SAR is calculated. Treatment was planned for an applicator with twelve antenna elements (six elements in one ring) operating at 434 MHz. The results of this study show the benefits of using TRF in the hyperthermic treatment of glioblastoma. Better results were achieved for small tumors with regular shapes. The total volume was not targeted for larger tumors but only the part where the virtual source was located. The advantage of this method is that there is no significant absorption of the SAR outside the tumor tissue, and therefore no hotspots should occur.

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时间逆转的实施聚焦于脑肿瘤热疗治疗

根据NBTS (National Brain Tumor Society)，胶质母细胞瘤是最常见的原发性恶性脑肿瘤[1]。目前的研究表明，对这些脑肿瘤进行热疗和放射治疗是有益的。热疗治疗计划(HTP)用于治疗指导。HTP通常分为三个单独的步骤:分割、电磁(EM)模拟和相位振幅优化。利用基于特定吸收率(SAR)或基于温度的优化方法，找到天线元件输入信号的最佳相位和幅度。基于sar优化的主要优势在于速度和计算复杂度，但这些优化需要考虑人体和水的冷却机制。目前，基于sar的优化方法有粒子群优化(PSO)、Nelder-Mead单纯形算法(NMS)、遗传算法(GA)、时间反转聚焦(TRF)等。时间反转聚焦分为正反两个步骤。首先，将虚拟电磁源置于肿瘤中。根据[2]，它不是直接到中心的合适源;如果源靠近肿瘤表面，效果会更好。接下来，波前从一个虚拟位置的源传播，由外围天线元件记录。这些信号被时间反转以检测振幅和相位。在第二步中，设置这些值，并计算SAR。治疗计划在一个涂抹器上使用12个天线元件(6个元件在一个环中)，工作频率为434 MHz。本研究的结果表明，使用TRF热疗胶质母细胞瘤的好处。对于形状规则的小肿瘤，效果更好。对于较大的肿瘤，只针对虚拟源所在的部分，而不针对总体积。这种方法的优点是肿瘤组织外对SAR没有明显的吸收，因此不会出现热点。

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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2023 Photonics & Electromagnetics Research Symposium (PIERS)

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