Characterizing Temperature-Dependent Acoustic and Thermal Tissue Properties for High-Intensity Focused Ultrasound Computational Modeling

IF 2.5 4区 工程技术 Q3 CHEMISTRY, PHYSICAL
Sarah G. Sanderson, Brian Easthope, Caio Farias, Isaac Doddridge, Jason A. Cook, David B. Dahl, Christopher R. Dillon
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Abstract

High-intensity focused ultrasound (HIFU) thermal therapies utilize concentrated sound waves to ablate diseased tissue at precise locations within the body. Computational simulations of HIFU can assist clinicians by predicting the death of target tissues, identifying sensitive healthy tissues that risk thermal damage, and optimizing acoustic power delivery to minimize treatment times and maximize treatment efficacy. Accurate simulations require accurate inputs, and many computational solvers neglect property changes induced by tissue heating during treatment. Additionally, temperature-dependent tissue property data in the literature are relatively scarce. This study presents methodology for characterizing temperature-dependent acoustic and thermal properties in ex vivo porcine muscle tissue. From 20 – 50 °C, speed of sound is found to increase from approximately 1580 – 1620 m/s. The acoustic attenuation coefficient increases for 20 – 50 °C from 0.09 – 0.24 Np/cm at 0.5 MHz and 0.16 – 0.37 Np/cm at 1.6 MHz. Thermal conductivity and thermal diffusivity increase from 0.52 – 0.55 W/m °C and 0.147 – 0.158 mm2/s, respectively, over 20 – 60 °C. Specific heat capacity increases from approximately 3500 – 3800 J/kg °C, over 20 – 80 °C. Each property is consistent with data found in the literature, extends the literature to a larger temperature range, and, for acoustic properties, extends to unique frequencies. Temperature-dependent predictive models are also developed for each of the five properties. This study’s property measurement methodologies can be used to characterize other biological tissues, and the predictive models developed herein will facilitate future efforts in temperature-dependent modeling and uncertainty quantification of HIFU thermal therapies.

为高强度聚焦超声计算建模确定与温度相关的声学和热学组织特性
高强度聚焦超声(HIFU)热疗法利用集中的声波消融体内精确位置的病变组织。HIFU 的计算模拟可以帮助临床医生预测目标组织的死亡,识别有热损伤风险的敏感健康组织,并优化声功率传输,从而最大限度地缩短治疗时间和提高治疗效果。精确的模拟需要精确的输入,而许多计算求解器忽略了治疗过程中组织加热引起的属性变化。此外,文献中与温度相关的组织特性数据相对较少。本研究介绍了表征体外猪肌肉组织随温度变化的声学和热学特性的方法。研究发现,从 20 - 50 °C,声速大约从 1580 米/秒增加到 1620 米/秒。声学衰减系数在 20 - 50 °C、0.5 MHz 和 1.6 MHz 时分别为 0.09 - 0.24 Np/cm 和 0.16 - 0.37 Np/cm。热导率和热扩散率在 20 - 60 °C 间分别从 0.52 - 0.55 W/m °C 和 0.147 - 0.158 mm2/s 增加。比热容在 20 - 80 °C 范围内从大约 3500 - 3800 J/kg °C 增加。每种特性都与文献中的数据一致,并将文献中的数据扩展到更大的温度范围,而声学特性则扩展到独特的频率。此外,还为五种特性中的每一种特性开发了与温度相关的预测模型。本研究的特性测量方法可用于描述其他生物组织的特性,本文所开发的预测模型将有助于未来 HIFU 热疗法的温度依赖性建模和不确定性量化工作。
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
CiteScore
4.10
自引率
9.10%
发文量
179
审稿时长
5 months
期刊介绍: International Journal of Thermophysics serves as an international medium for the publication of papers in thermophysics, assisting both generators and users of thermophysical properties data. This distinguished journal publishes both experimental and theoretical papers on thermophysical properties of matter in the liquid, gaseous, and solid states (including soft matter, biofluids, and nano- and bio-materials), on instrumentation and techniques leading to their measurement, and on computer studies of model and related systems. Studies in all ranges of temperature, pressure, wavelength, and other relevant variables are included.
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