Feasibility of Ultrasonic Heating through Skull Phantom Using Single-element Transducer.

IF 0.9 Q4 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Journal of Medical Ultrasound Pub Date : 2023-08-03 eCollection Date: 2024-01-01 DOI:10.4103/jmu.jmu_3_23

Anastasia Antoniou, Christakis Damianou

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Abstract

Background: Noninvasive neurosurgery has become possible through the use of transcranial focused ultrasound (FUS). This study assessed the heating ability of single element spherically focused transducers operating at 0.4 and 1.1 MHz through three-dimensional (3D) printed thermoplastic skull phantoms.

Methods: Phantoms with precise skull bone geometry of a male patient were 3D printed using common thermoplastic materials following segmentation on a computed tomography head scan image. The brain tissue was mimicked by an agar-based gel phantom developed in-house. The selection of phantom materials was mainly based on transmission-through attenuation measurements. Phantom sonications were performed through water, and then, with the skull phantoms intervening the beam path. In each case, thermometry was performed at the focal spot using thermocouples.

Results: The focal temperature change in the presence of the skull phantoms was reduced to less than 20 % of that recorded in free field when using the 0.4 MHz transducer, whereas the 1.1 MHz trans-skull sonication produced minimal or no change in focal temperature. The 0.4 MHz transducer showed better performance in trans-skull transmission but still not efficient.

Conclusion: The inability of both tested single element transducers to steer the beam through the high attenuating skull phantoms and raise the temperature at the focus was confirmed, underlying the necessity to use a correction technique to compensate for energy losses, such those provided by phased arrays. The proposed phantom could be used as a cost-effective and ergonomic tool for trans-skull FUS preclinical studies.

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使用单元件换能器通过颅骨模型进行超声波加热的可行性

背景：通过使用经颅聚焦超声（FUS），无创神经外科手术已成为可能。本研究通过三维（3D）打印热塑头骨模型，评估了工作频率为 0.4 和 1.1 MHz 的单元件球形聚焦换能器的加热能力：方法：在对计算机断层扫描头部扫描图像进行分割后，使用普通热塑性材料三维打印出具有男性患者精确颅骨几何形状的模型。脑组织由内部开发的琼脂凝胶模型模拟。模型材料的选择主要基于透射衰减测量结果。首先通过水，然后在头骨模型干扰光束路径的情况下进行模型超声。在每种情况下，都使用热电偶对焦点进行测温：结果：使用 0.4 MHz 声变换器时，在有头骨模型存在的情况下，病灶温度的变化减小到自由场记录的 20% 以下，而 1.1 MHz 跨头骨声波疗法产生的病灶温度变化极小或没有变化。0.4 兆赫换能器在跨颅骨传输方面表现较好，但效率仍然不高：测试的两个单元件换能器都无法引导光束穿过高衰减颅骨模型，也无法提高焦点处的温度，这说明有必要使用校正技术来补偿能量损失，如相控阵提供的能量损失。所提出的模型可作为一种成本效益高且符合人体工学的工具，用于跨颅骨 FUS 临床前研究。

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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来源期刊

Journal of Medical Ultrasound RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-

CiteScore

1.30

自引率

9.10%

发文量

审稿时长

10 weeks

期刊介绍： The Journal of Medical Ultrasound is the peer-reviewed publication of the Asian Federation of Societies for Ultrasound in Medicine and Biology, and the Chinese Taipei Society of Ultrasound in Medicine. Its aim is to promote clinical and scientific research in ultrasonography, and to serve as a channel of communication among sonologists, sonographers, and medical ultrasound physicians in the Asia-Pacific region and wider international community. The Journal invites original contributions relating to the clinical and laboratory investigations and applications of ultrasonography.