Bioheat transfer analysis of biological tissues induced by laser irradiation

Hooshmand, Payam; Moradi, Amir; Khezry, B.

doi:10.1016/j.ijthermalsci.2014.12.004

Cited by 82 publications

(29 citation statements)

References 30 publications

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“…t 4 7 31 . The values of the relevant thermal parameters which have been used in the present calculations are in Table 1 as following 4,16,19,29,31 :…”

Section: Formulation Of the Problemmentioning

confidence: 99%

“…It is observed that even a small increment of heat-induced stress can destroy the immune response; protein cell organelle structures can be changed, resulting in cell death 1 . Most studies emphasis on heat conduction [9][10][11][12][13][14][15][16][17][18][19][20] , while the heating which induced deformation is not considered. Tunc 21 solved the bioheat transfer equation considering variable blood perfusion values and the temperature field in the context of the Pennes's model.…”

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confidence: 99%

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Modeling of One-Dimensional Thermoelastic Dual-Phase-Lag Skin Tissue Subjected to Different Types of Thermal Loading

Youssef

Alghamdi

2020

Sci Rep

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this work introduces a mathematical model of thermoelastic skin tissue in the context of the dualphase-lag heat conduction law. One-dimensional skin tissue has been considered with a small thickness and its outer surface traction free. The bounding plane of the skin tissue is subjected to three different types of thermal loading; thermal shock, ramp type heating, and harmonic heating. The inner surface has no temperature increment and traction free. Laplace transform techniques have been used, and its inversions have been calculated by using the Tzuo method. The numerical results have been represented in figures. The thermal shock time parameter, the ramp-type heat parameter, and the angular thermal parameter have significant effects on the temperature increment, the strain, the displacement, and the stress distributions, and they play vital roles in the speed propagation of the thermomechanical waves through the skin tissue.

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“…t 4 7 31 . The values of the relevant thermal parameters which have been used in the present calculations are in Table 1 as following 4,16,19,29,31 :…”

Section: Formulation Of the Problemmentioning

confidence: 99%

mentioning

confidence: 99%

Modeling of One-Dimensional Thermoelastic Dual-Phase-Lag Skin Tissue Subjected to Different Types of Thermal Loading

Youssef

Alghamdi

2020

Sci Rep

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“…At the end of this section we have to refer to some additional studies applying the dual-phase-lag approach to modeling bioheat problem. The dominating studies are on the Pennes model, among them: laser radiation heat supply to the tissue [108], temperature-dependent perfusion [109], skin heat transfer [14], pulsed IR irradiation [106], cryosurgery of lung cancer [110], laser heating [111,112], interaction between tissue and a cryoprobe [113,114], human head relaxation times [115]. The main idea of the DPL, that is the Taylor series expansions of the integer-order heat conduction equation, thus creating damping and heat wave behavior, is fruitfully used in fractionalization of bio-heat models (see section 8.4).…”

Section: Closing Briefs On the Dpl Modelsmentioning

confidence: 99%

Bio-Heat Models Revisited: Concepts, Derivations, Nondimensalization and Fractionalization Approaches

Hristov

2019

Front. Phys.

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The heat transfer in living tissues is an evergreen problem in mathematical modeling with great practical importance starting from the Pennes equation postulation. This study focuses on concept in model building, the correct scaling of the bio-heat equation (one-dimensional) by appropriate choice of time and length scales, and consequently order of magnitude analysis of effects, as well as fractionalization approaches. Fractionalization by different constitutive approaches, leading to application of different fractional differential operators, modeling the finite speed of the heat wave, is one of the principle problems discussed in the study. The correct choice of the damping (relaxation) function of the heat flux is of primarily importance in the formulation of the bio-heat equation with memory. Moreover, this affects the consequent scaling, order of magnitude analysis and solutions.

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“…The modeling of biological tissues using the dual phase lag model helps to analyse the heterogeneous nature of the tissues. Hooshmand et al(2015) discusses an analytical solution for non-equillibrium heat transfer in biological tissues subjected to laser heating, modeled using the generalized dual phase lag model. The solution to the volume averaged local energy equation was arrived at using the separation of variables and Duhamel's integration methods.…”

Section: Non-conventional Theoretical Modelsmentioning

confidence: 99%

Microscale Transport Phenomena for Bio-Engineering Applications: Recent Advances

Sobhan¹,

Thomas²,

Peterson³

2017

JAN

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Abstract. The importance of microscale thermal energy transport has dramatically increased in the past several years and a number of significant investigations have been undertaken to better understand the fundamental phenomena that govern the behavior of energy transport at the microscale. While the original focus of this research was directed towards the thermal management of semiconductor devices and spacecraft thermal control, there has been an increased interest in the thermophysical phenomena occurring in biological systems, and bio-medical devices and applications. As a result a number of investigations have been reported, in which the thermal transport phenomena in microscale systems and passages are of significant importance. In this context, this following attempts to review the relevant literature on the theoretical and experimental investigations of microscale transport phenomena as specifically related to bioengineering and biomedical applications. Modeling methodologies, experimental studies, instrumentation techniques and research leading to the development of optimal bio-medical systems are reviewed and discussed.

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Bioheat transfer analysis of biological tissues induced by laser irradiation

Cited by 82 publications

References 30 publications

Modeling of One-Dimensional Thermoelastic Dual-Phase-Lag Skin Tissue Subjected to Different Types of Thermal Loading

Modeling of One-Dimensional Thermoelastic Dual-Phase-Lag Skin Tissue Subjected to Different Types of Thermal Loading

Bio-Heat Models Revisited: Concepts, Derivations, Nondimensalization and Fractionalization Approaches

Microscale Transport Phenomena for Bio-Engineering Applications: Recent Advances

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