Analysis of temperature changes in living tissue using the modified fractional thermal conduction model under laser heat flux on the skin surface

IF 1.9 4区工程技术 Q3 MECHANICS

Continuum Mechanics and Thermodynamics Pub Date : 2024-12-10 DOI:10.1007/s00161-024-01343-y

Ahmed E. Abouelregal, Rasmiyah A. Alharb, Murat Yaylacı, Badahi Ould Mohamed, Sami F. Megahid

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引用次数: 0

Abstract

The use of thermal conduction models, particularly the double-phase lag thermal wave model, is vital for improving thermal therapies in biological tissues. However, existing models have limitations that hinder their practical application. This paper introduces a modified Pennes fractional thermal equation for biological heat transfer that integrates the double-phase lag concept and the fractional Atangana-Baleanu operator with a non-singular kernel. The model’s predictions were validated against measured temperature responses of laser-irradiated skin tissue and compared to established models. A one-dimensional layer of human skin tissue was analyzed using the Laplace transform method, with graphical results for each scenario. The comparative analysis showed that the AB fractional model outperforms other fractional models in capturing memory effects related to temperature variations and accurately models thermal interactions in living tissues while considering time delays. These findings highlight the model’s potential to improve the design and optimization of thermal therapies in clinical practice.

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使用热传导模型，特别是双相滞后热波模型，对于改善生物组织的热疗法至关重要。然而，现有模型存在局限性，阻碍了其实际应用。本文介绍了一种用于生物热传导的修正彭尼斯分数热方程，该方程将双相滞后概念和分数阿坦加纳-巴莱阿努算子与非星形核整合在一起。该模型的预测结果与激光照射皮肤组织的实测温度响应进行了验证，并与已建立的模型进行了比较。使用拉普拉斯变换方法分析了一层一维的人体皮肤组织，并对每种情况给出了图形结果。对比分析表明，AB 分数模型在捕捉与温度变化相关的记忆效应方面优于其他分数模型，并能在考虑时间延迟的情况下准确模拟活体组织中的热相互作用。这些发现凸显了该模型在改善临床实践中热疗法的设计和优化方面的潜力。

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

Continuum Mechanics and Thermodynamics 物理-力学

CiteScore

5.30

自引率

15.40%

发文量

审稿时长

>12 weeks

期刊介绍： This interdisciplinary journal provides a forum for presenting new ideas in continuum and quasi-continuum modeling of systems with a large number of degrees of freedom and sufficient complexity to require thermodynamic closure. Major emphasis is placed on papers attempting to bridge the gap between discrete and continuum approaches as well as micro- and macro-scales, by means of homogenization, statistical averaging and other mathematical tools aimed at the judicial elimination of small time and length scales. The journal is particularly interested in contributions focusing on a simultaneous description of complex systems at several disparate scales. Papers presenting and explaining new experimental findings are highly encouraged. The journal welcomes numerical studies aimed at understanding the physical nature of the phenomena. Potential subjects range from boiling and turbulence to plasticity and earthquakes. Studies of fluids and solids with nonlinear and non-local interactions, multiple fields and multi-scale responses, nontrivial dissipative properties and complex dynamics are expected to have a strong presence in the pages of the journal. An incomplete list of featured topics includes: active solids and liquids, nano-scale effects and molecular structure of materials, singularities in fluid and solid mechanics, polymers, elastomers and liquid crystals, rheology, cavitation and fracture, hysteresis and friction, mechanics of solid and liquid phase transformations, composite, porous and granular media, scaling in statics and dynamics, large scale processes and geomechanics, stochastic aspects of mechanics. The journal would also like to attract papers addressing the very foundations of thermodynamics and kinetics of continuum processes. Of special interest are contributions to the emerging areas of biophysics and biomechanics of cells, bones and tissues leading to new continuum and thermodynamical models.