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Computational Thermal Sciences: An International Journal

Publicou 6 edições por ano

ISSN Imprimir: 1940-2503

ISSN On-line: 1940-2554

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SIMPLIFIED APPROACHES TO RADIATIVE TRANSFER SIMULATIONS IN LASER-INDUCED HYPERTHERMIA OF SUPERFICIAL TUMORS

Volume 5, Edição 6, 2013, pp. 521-530
DOI: 10.1615/ComputThermalScien.2013008157
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Leonid A. Dombrovsky
Joint Institute for High Temperatures, Russian Academy of Sciences, Moscow, 111116, Russia; University of Tyumen, 6 Volodarskogo St, Tyumen 625003, Russia
National Committee of Heat and Mass Transfer (NCHMT)
Jaona Harifidy Randrianalisoa
Centre de Thermique de Lyon, Institut National des Sciences Appliqués, Lyon; GRESPI - EA 4694, University of Reims Champagne-Ardenne, F-51687 Reims, France; Institut de Thermique, Mecanique, Materiaux (ITheMM), EA 7548, Campus du Moulin de la Housse - BP 1039, 51687 Reims Cedex 2, France
Wojciech Lipinski
The Cyprus Institute
Victoria Timchenko
School of Mechanical and Manufacturing Engineering, The University of New South Wales, Sydney, NSW, 2052, Australia

RESUMO

A promising approach to the treatment of superficial human cancer is laser-induced hyperthermia. The correct choice of the parameters used for the treatment planning should be based on modeling of both radiative transfer and transient heating of human tissues, which will allow predicting the thermal conversions in the tumor. In this paper, we focus on radiative transfer modeling, which should be as simple as possible for implementation into a combined heat transfer model. In general, the well-known P1 approximation is known to be sufficiently accurate in calculations of the absorbed radiation power distribution. At the same time, errors in this approximation may increase in the case of external irradiation, and thus it needs to be examined by comparison with direct Monte Carlo simulation. A computational study with realistic geometrical and optical parameters of the problem undertaken in this work showed that the P1 approximation considerably underestimates the intense absorption near the body surface in comparison with the direct Monte Carlo solution. At the same time, it has been shown that a one-dimensional solution for radiative transfer can be used as a valid approach due to intense scattering of radiation by tissues. As a result, the modified two-flux approximation is recommended as a component of the multidimensional combined heat transfer model for soft thermal treatment of superficial tumors.

Palavras-chave: radiative transfer, biological tissues, laser-induced hyperthermia, computational methods, differential approximations, Monte Carlo method
CITADO POR

  1. Randrianalisoa Jaona H., Dombrovsky Leonid A., Lipiński Wojciech, Timchenko Victoria, Effects of short-pulsed laser radiation on transient heating of superficial human tissues, International Journal of Heat and Mass Transfer, 78, 2014. Crossref

  2. Dombrovsky Leonid A., A new method to retrieve spectral absorption coefficient of highly-scattering and weakly-absorbing materials, Journal of Quantitative Spectroscopy and Radiative Transfer, 172, 2016. Crossref

  3. Wang Keyong, Tavakkoli Fatemeh, Wang Shujuan, Vafai Kambiz, Analysis and analytical characterization of bioheat transfer during radiofrequency ablation, Journal of Biomechanics, 48, 6, 2015. Crossref

  4. Dombrovsky Leonid A., Timchenko Victoria, Pathak Chinmay, Piazena Helmut, Müller Werner, Jackson Michael, Radiative heating of superficial human tissues with the use of water-filtered infrared-A radiation: A computational modeling, International Journal of Heat and Mass Transfer, 85, 2015. Crossref

  5. Kumar Sumit, Srivastava Atul, Thermal analysis of laser-irradiated tissue phantoms using dual phase lag model coupled with transient radiative transfer equation, International Journal of Heat and Mass Transfer, 90, 2015. Crossref

  6. Jasiński M., Majchrzak E., Turchan L., Numerical analysis of the interactions between laser and soft tissues using generalized dual-phase lag equation, Applied Mathematical Modelling, 40, 2, 2016. Crossref

  7. Kumar Sumit, Srivastava Atul, Numerical investigation of the influence of pulsatile blood flow on temperature distribution within the body of laser-irradiated biological tissue phantoms, International Journal of Heat and Mass Transfer, 95, 2016. Crossref

  8. Varon Leonardo Antonio Bermeo, Orlande Helcio Rangel Barreto, Eliçabe Guillermo Enrique, Combined parameter and state estimation in the radio frequency hyperthermia treatment of cancer, Numerical Heat Transfer, Part A: Applications, 70, 6, 2016. Crossref

  9. Patidar Shashank, Kumar Sumit, Srivastava Atul, Singh Suneet, Dual phase lag model-based thermal analysis of tissue phantoms using lattice Boltzmann method, International Journal of Thermal Sciences, 103, 2016. Crossref

  10. Phadnis Akshay, Kumar Sumit, Srivastava Atul, Numerical investigation of thermal response of laser-irradiated biological tissue phantoms embedded with gold nanoshells, Journal of Thermal Biology, 61, 2016. Crossref

  11. Randrianalisoa Jaona, Haussener Sophia, Baillis Dominique, Lipiński Wojciech, Radiative characterization of random fibrous media with long cylindrical fibers: Comparison of single- and multi-RTE approaches, Journal of Quantitative Spectroscopy and Radiative Transfer, 202, 2017. Crossref

  12. Nirgudkar Himanshu, Kumar Sumit, Srivastava Atul, Thermal analysis of laser-irradiated tissue phantoms using a novel separation of the variables-based discrete transfer method, Numerical Heat Transfer, Part A: Applications, 71, 5, 2017. Crossref

  13. Mitra Kunal, Miller Stephanie, Introduction, in Short Pulse Laser Systems for Biomedical Applications, 2017. Crossref

  14. Dombrovsky Leonid A., Lipinski Wojciech, Simple methods for identification of radiative properties of highly-porous ceria ceramics in the range of semi-transparency, International Journal of Numerical Methods for Heat & Fluid Flow, 27, 5, 2017. Crossref

  15. Majchrzak Ewa, Jasiński Marek, Turchan Łukasz, Modeling of Laser-Soft Tissue Interactions Using the Dual-Phase Lag Equation: Sensitivity Analysis with Respect to Selected Tissue Parameters, Defect and Diffusion Forum, 379, 2017. Crossref

  16. Dombrovsky Leonid A., Randrianalisoa Jaona H., Directional reflectance of optically dense planetary atmosphere illuminated by solar light: An approximate solution and its verification, Journal of Quantitative Spectroscopy and Radiative Transfer, 208, 2018. Crossref

  17. Dombrovsky Leonid A., Dembele Siaka, Wen Jennifer X., Sikic Ivan, Two-step method for radiative transfer calculations in a developing pool fire at the initial stage of its suppression by a water spray, International Journal of Heat and Mass Transfer, 127, 2018. Crossref

  18. Lamien Bernard, Barreto Orlande Helcio Rangel, Enrique Eliçabe Guillermo, Particle Filter and Approximation Error Model for State Estimation in Hyperthermia, Journal of Heat Transfer, 139, 1, 2017. Crossref

  19. Shamekhi Leila, Sayehvand Habib‐Olah, Karami Hamidreza, Electromagnetic hyperthermia on porous model of hepatic cancerous tissue, International Journal of Numerical Modelling: Electronic Networks, Devices and Fields, 33, 2, 2020. Crossref

  20. Dombrovsky Leonid A., Scattering of Radiation and Simple Approaches to Radiative Transfer in Thermal Engineering and Biomedical Applications, in Springer Series in Light Scattering, 2019. Crossref

  21. Pereira Gomes Isabela, Aparecida Duarte Jaqueline, Chaves Maia Ana Luiza, Rubello Domenico, Townsend Danyelle M., Branco de Barros André Luís, Leite Elaine Amaral, Thermosensitive Nanosystems Associated with Hyperthermia for Cancer Treatment, Pharmaceuticals, 12, 4, 2019. Crossref

  22. Dombrovsky Leonid A., Levashov Vladimir Yu, Kryukov Alexei P., Dembele Siaka, Wen Jennifer X., A comparative analysis of shielding of thermal radiation of fires using mist curtains containing droplets of pure water or sea water, International Journal of Thermal Sciences, 152, 2020. Crossref

  23. Dombrovsky Leonid A., Kokhanovsky Alexander A., Solar heating of ice sheets containing gas bubbles, Journal of Quantitative Spectroscopy and Radiative Transfer, 250, 2020. Crossref

  24. Dombrovsky Leonid A., Kokhanovsky Alexander A., Solar Heating of the Cryosphere: Snow and Ice Sheets, in Springer Series in Light Scattering, 2021. Crossref

  25. Dombrovsky Leonid A., Laser-Induced Thermal Treatment of Superficial Human Tumors: An Advanced Heating Strategy and Non-Arrhenius Law for Living Tissues, Frontiers in Thermal Engineering, 1, 2022. Crossref

  26. Dombrovsky Leonid A., Kokhanovsky Alexander A., Deep Heating of a Snowpack by Solar Radiation, Frontiers in Thermal Engineering, 2, 2022. Crossref

  27. Dombrovsky Leonid A., Kokhanovsky Alexander A., Randrianalisoa Jaona H., On snowpack heating by solar radiation: A computational model, Journal of Quantitative Spectroscopy and Radiative Transfer, 227, 2019. Crossref

  28. Dombrovsky Leonid A., Solovjov Vladimir P., Webb Brent W., Effect of ground-based environmental conditions on the level of dangerous ultraviolet solar radiation, Journal of Quantitative Spectroscopy and Radiative Transfer, 279, 2022. Crossref

  29. Ren Yatao, Yan Yuying, Qi Hong, Photothermal conversion and transfer in photothermal therapy: From macroscale to nanoscale, Advances in Colloid and Interface Science, 308, 2022. Crossref

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