Assessment of thermochromic phantoms for characterizing microwave ablation devices

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Medical physics Pub Date : 2024-09-17 DOI:10.1002/mp.17404

Ghina Zia, Amber Lintz, Clay Hardin, Anna Bottiglieri, Jan Sebek, Punit Prakash

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Abstract

Background and purpose

Thermochromic gel phantoms provide a controlled medium for visual assessment of thermal ablation device performance. However, there are limited studies reporting on the comparative assessment of ablation profiles assessed in thermochromic gel phantoms against those in ex vivo tissue. The objective of this study was to compare microwave ablation zones in a thermochromic tissue-mimicking gel phantom and ex vivo bovine liver and to report on measurements of the temperature-dependent dielectric and thermal properties of the phantom.

Methods

Thermochromic polyacrylamide phantoms were fabricated following a previously reported protocol. Phantom samples were heated to temperatures in the range of 20°C–90°C in a temperature-controlled water bath, and colorimetric analysis of images of the phantom taken after heating was used to develop a calibration between color changes and the temperature to which the phantom was heated. Using a custom, 2.45 GHz water-cooled microwave ablation antenna, ablations were performed in fresh ex vivo liver and phantoms using 65 W applied for 5 min or 10 min (n = 3 samples in each medium for each power/time combination). Broadband (500 MHz–6 GHz) temperature-dependent dielectric and thermal properties of the phantom were measured over the temperature range of 22°C–100°C.

Results

Colorimetric analysis showed that the sharp change in gel phantom color commences at a temperature of 57°C. Short and long axes of the ablation zone in the phantom (as assessed by the 57°C isotherm) for 65 W, 5 min ablations were aligned with the extents of the ablation zone observed in ex vivo bovine liver. However, for the 65 W, 10 min setting, ablations in the phantom were on average 23.7% smaller in the short axis and 7.4 % smaller in the long axis than those observed in ex vivo liver. Measurements of the temperature-dependent relative permittivity, thermal conductivity, and volumetric heat capacity of the phantom largely followed similar trends to published values for ex vivo liver tissue.

Conclusion

Thermochromic tissue-mimicking phantoms provides a controlled, and reproducible medium for comparative assessment of microwave ablation devices and energy delivery settings. However, ablation zone size and shapes in the thermochromic phantom do not accurately represent ablation sizes and shapes observed in ex vivo liver tissue for high energy delivery treatments (65 W, 10 min). One cause for this limitation is the difference in temperature-dependent thermal and dielectric properties of the thermochromic phantom compared to ex vivo bovine liver tissue, as reported in the present study.

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评估微波消融设备特性的热致变色模型

背景和目的热致变色凝胶模型为热消融设备性能的可视化评估提供了受控介质。然而，有关热致变色凝胶模型中的消融曲线与体内外组织中的消融曲线进行比较评估的研究报告十分有限。本研究的目的是比较热致变色组织模拟凝胶模型和体外牛肝中的微波消融区，并报告模型随温度变化的介电性能和热性能的测量结果。在温控水浴中将模型样品加热到 20°C-90°C 的温度范围内，并对加热后拍摄的模型图像进行比色分析，以建立颜色变化与模型加热温度之间的校准关系。使用定制的 2.45 GHz 水冷微波消融天线，在新鲜的活体肝脏和模型中进行消融，消融功率为 65 W，持续时间为 5 分钟或 10 分钟（每种功率/时间组合在每种介质中的样本数为 3 个）。结果色度分析表明，凝胶模型颜色的急剧变化始于 57°C 的温度。在 65 瓦、5 分钟的消融过程中，模型中消融区的短轴和长轴（根据 57°C 等温线评估）与在体外牛肝中观察到的消融区范围一致。然而，在 65 瓦、10 分钟的设置下，模型中的消融区与在体外肝脏中观察到的消融区相比，短轴平均小 23.7%，长轴平均小 7.4%。对模型随温度变化而变化的相对介电常数、热导率和体积热容的测量结果与已公布的活体肝脏组织数值的趋势基本相似。然而，热致变色模型中的消融区大小和形状并不能准确代表高能量输送治疗（65 瓦，10 分钟）时在体外肝组织中观察到的消融大小和形状。造成这种局限性的原因之一是，如本研究报告所述，热致变色模型与活体牛肝组织相比，在随温度变化而变化的热和介电特性方面存在差异。

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来源期刊

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.

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