Uncertainties in the Micro/nano-Particles Induced Hyperthermia Treatment on Tumor Subject to External EM Field

Z. Deng, Jing Liu
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引用次数: 1

Abstract

Advancement of the recent micro/nano technology has stimulated the renaissance of using magnetic micro/nano particles embedded in biological tissues for the target tumor hyperthermia. As is well known, mathematical solutions of bioheat transfer involved in hyperthermia treatment are indispensable for computerized optimization of hyperthermia parameters. However, estimating the level of uncertainties associated with tissue temperature and thermal ablation area remains a major challenge. In this article, the uncertainties for the predicted temperatures of tissues due to approximate parameters were studied, based on numerical simulation of three-dimensional (3-D) quasi-steady state electromagnetic (EM) field and transient temperature response in biological tissues induced by the external EM field. Contributions of uncertainty from the tissue area permeated with micro/nano particles, the concentration and size of micro/nano particles, and the frequency and strength of the external alternating EM field were analyzed, and the uncertainty limits for temperature distributions in these cases were also estimated. The uncertainty analysis presented in this article is expected to serve as a significant guide for performing a highly efficient and also completely safe tumor hyperthermia using magnetic micro/nano particles.
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微纳米粒子诱导热疗治疗外源电磁场下肿瘤的不确定性
近年来微纳米技术的进步刺激了磁性微纳米颗粒嵌入生物组织用于靶肿瘤热疗的复兴。众所周知,热疗过程中生物热传递的数学解对于热疗参数的计算机优化是必不可少的。然而,估计与组织温度和热消融面积相关的不确定性水平仍然是一个主要挑战。本文基于三维准稳态电磁场的数值模拟和外源电磁场对生物组织瞬态温度响应的数值模拟,研究了由于参数近似导致的组织温度预测的不确定性。分析了微纳粒子渗透的组织面积、微纳粒子的浓度和大小、外加交变电磁场的频率和强度对温度分布的不确定度贡献,并估计了这些情况下温度分布的不确定度限。本文提出的不确定性分析有望为使用磁性微/纳米颗粒进行高效且完全安全的肿瘤热疗提供重要指导。
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