Three-Phase-Lag Bio-Heat Transfer Model of Cardiac Ablation

Singh, Sundeep; Saccomandi, Paola; Melnik, Roderick

doi:10.3390/fluids7050180

Cited by 11 publications

(4 citation statements)

References 60 publications

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“…, beyond 76 °C) 10 , 48 which are reached during localized thermal therapies on these organs. 8 , 29 , 51 Hence, motivated by the limited data on heart and lung, and by the huge demand for accurate models for describing the heat transfer in these organs, this paper focuses on the measurement of the thermal properties of these tissues, from room temperature up to 94 °C. The thermal conductivity, thermal diffusivity, and volumetric heat capacity of ex vivo porcine heart and lung were measured with a dual-needle sensor technique, which has been previously validated by our group on other organs.…”

Section: Introductionmentioning

confidence: 99%

Temperature Dependence of Thermal Properties of Ex Vivo Porcine Heart and Lung in Hyperthermia and Ablative Temperature Ranges

et al. 2023

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This work proposes the characterization of the temperature dependence of the thermal properties of heart and lung tissues from room temperature up to > 90 °C. The thermal diffusivity (α), thermal conductivity (k), and volumetric heat capacity (Cv) of ex vivo porcine hearts and deflated lungs were measured with a dual-needle sensor technique. α and k associated with heart tissue remained almost constant until ~ 70 and ~ 80 °C, accordingly. Above ~ 80 °C, a more substantial variation in these thermal properties was registered: at 94 °C, α and k respectively experienced a 2.3- and 1.5- fold increase compared to their nominal values, showing average values of 0.346 mm2/s and 0.828 W/(m·K), accordingly. Conversely, Cv was almost constant until 55 °C and decreased afterward (e.g., Cv = 2.42 MJ/(m3·K) at 94 °C). Concerning the lung tissue, both its α and k were characterized by an exponential increase with temperature, showing a marked increment at supraphysiological and ablative temperatures (at 91 °C, α and k were equal to 2.120 mm2/s and 2.721 W/(m·K), respectively, i.e., 13.7- and 13.1-fold higher compared to their baseline values). Regression analysis was performed to attain the best-fit curves interpolating the measured data, thus providing models of the temperature dependence of the investigated properties. These models can be useful for increasing the accuracy of simulation-based preplanning frameworks of interventional thermal procedures, and the realization of tissue-mimicking materials.

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Section: Introductionmentioning

confidence: 99%

Temperature Dependence of Thermal Properties of Ex Vivo Porcine Heart and Lung in Hyperthermia and Ablative Temperature Ranges

et al. 2023

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“…The accuracy of temperature prediction with the governing equations of different bioheat transfer models presented in " Materials and Methods " section tremendously depends on the thermal properties of the tissue under consideration. It is a common practice to treat the thermal properties of the tissue (viz., thermal conductivity, volumetric heat capacity, and thermal diffusivity) as constant, generally at room temperature, during computational modeling of thermal therapies [ 10 , 32 , 33 , 36 , 47 , 49 , 52 , 53 ]. This simplified assumption is also considered due to the lack of experimental data available in the literature related to the thermal characterization of biological tissues in the temperature range applicable for thermal therapies [ 54 ].…”

Section: Discussionmentioning

confidence: 99%

Non-Fourier Bioheat Transfer Analysis in Brain Tissue During Interstitial Laser Ablation: Analysis of Multiple Influential Factors

Singh,

Bianchi,

Korganbayev

et al. 2024

Ann Biomed Eng

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This work presents the dual-phase lag-based non-Fourier bioheat transfer model of brain tissue subjected to interstitial laser ablation. The finite element method has been utilized to predict the brain tissue's temperature distributions and ablation volumes. A sensitivity analysis has been conducted to quantify the effect of variations in the input laser power, treatment time, laser fiber diameter, laser wavelength, and non-Fourier phase lags. Notably, in this work, the temperature-dependent thermal properties of brain tissue have been considered. The developed model has been validated by comparing the temperature obtained from the numerical and ex vivo brain tissue during interstitial laser ablation. The ex vivo brain model has been further extended to in vivo settings by incorporating the blood perfusion effects. The results of the systematic analysis highlight the importance of considering temperature-dependent thermal properties of the brain tissue, non-Fourier behavior, and microvascular perfusion effects in the computational models for accurate predictions of the treatment outcomes during interstitial laser ablation, thereby minimizing the damage to surrounding healthy tissue. The developed model and parametric analysis reported in this study would assist in a more accurate and precise prediction of the temperature distribution, thus allowing to optimize the thermal dosage during laser therapy in the brain.

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“…There are various types of mathematical models that describe the heat flow in living tissues in the literature. These are the Pennes equation [1], the Cattaneo-Vernotte equation [2,3], the dual-phase lag equation [4], the three-phase lag equation [5][6][7], models based on the theory of porous media [8] and models taking into account the presence of thermally significant blood vessels [9,10]. In order to determine the values of thermophysical parameters present in these models, intensive experimental studies of various types of tissues are carried out [11,12].…”

Section: Introductionmentioning

confidence: 99%

Numerical analysis of biological tissue heating using the dual-phase lag equation with temperature – dependent parameters

Majchrzak¹,

Stryczyński²

2022

J. Appl. Math. Comput. Mech.

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The dual-phase lag equation is formulated for the case when the thermophysical parameters occurring in this equation are temperature-dependent. The axial-symmetrical domain of biological tissue heated by an external heat source is considered. The problem is solved using the implicit scheme of the finite difference method. At the stage of numerical computations, the analytical relationships taken from the literature describing changes in parameters are taken into account.

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Three-Phase-Lag Bio-Heat Transfer Model of Cardiac Ablation

Cited by 11 publications

References 60 publications

Temperature Dependence of Thermal Properties of Ex Vivo Porcine Heart and Lung in Hyperthermia and Ablative Temperature Ranges

Temperature Dependence of Thermal Properties of Ex Vivo Porcine Heart and Lung in Hyperthermia and Ablative Temperature Ranges

Non-Fourier Bioheat Transfer Analysis in Brain Tissue During Interstitial Laser Ablation: Analysis of Multiple Influential Factors

Numerical analysis of biological tissue heating using the dual-phase lag equation with temperature – dependent parameters

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