Bioheat Transfer
Parisa Rahmani; Hossein Shamohammadi; Omid Abouali; Homayoon Emdad; Mohammad Faramarzi
Volume 13, Issue 1 , April 2019, , Pages 45-53
Abstract
Turbinates play an important role in conditioning of inhaled air and affect the airflow passing the nasal cavity. The purpose of this study is to investigate the effect of removing inferior turbinate on flow field, heat and moisture transfer from mucosa into the inhaled-air in a human nasal cavity and ...
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Turbinates play an important role in conditioning of inhaled air and affect the airflow passing the nasal cavity. The purpose of this study is to investigate the effect of removing inferior turbinate on flow field, heat and moisture transfer from mucosa into the inhaled-air in a human nasal cavity and comparison of them before and after the surgery. Turbinectomy was performed virtually on the computational model under the specialist’s supervision. In this study the airflow assumed to be laminar and unsteady. The nasal wall assumed to be rigid and no slip boundary condition was set. Moreover, the mucous layer assumed to be within fixed thickness in all over nasal cavity surface. The temperature and humidity distribution over the surface of mucusa are found by numerical computation. The results depict that conditioning of the nasal airway deteriorates by removing the inferior turbinate. For a specific air flow rate, both the heat and moisture flux averages decrease after surgery.
Bioheat Transfer
Farshad Bahramian; Afsaneh Mojra
Volume 10, Issue 3 , October 2016, , Pages 245-256
Abstract
The aim of this study is to investigate the use of thermography technique for detection of thyroid gland embedded in the neck through a numerical and an experimental approach. To this end, a real 3D model of the human neck and its primary organs including trachea, thyroid gland, common carotid artery ...
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The aim of this study is to investigate the use of thermography technique for detection of thyroid gland embedded in the neck through a numerical and an experimental approach. To this end, a real 3D model of the human neck and its primary organs including trachea, thyroid gland, common carotid artery and internal jugular vein is constructed based on the computerized tomography (CT) scan images of a healthy case and a case of thyroid cancer. The model is used for analyzing bio-heat transfer in the neck. In the thermal analysis the thyroid gland is considered as a heat source via specific function that generates heat based on the thyroid temporal temperature. Moreover, external convection through the neck skin surface and the ambient air, an internal convection through the inner layer of trachea and breathed air and heat transfer through the artery and the vein are considered. The result is the temperature distribution (thermogram) on the skin surface of the neck which reveals an approximate 0.5 -1.4 ˚C temperature increase on the area above thyroid gland for the healthy case. Studying effects of the thyroid cancer on the thermogram shows an approximate 0.7 -1.6 ˚C temperature increase due to the increased metabolic rate of the cancerous tumor compared to the healthy tissue. In order to practically investigate the applicability of thermography technique, a healthy case is examined by a high precision thermographic camera in similar conditions to the numerical simulation. Similar temperature increase due to the existence of the thyroid gland by the simulation and experiment affirmed the capability of the thermography method in the thyroid gland detection on the skin surface of the neck.
Bioheat Transfer
Mohammad Shams Kolahi; Ataollah Hashemi
Volume 5, Issue 1 , June 2011, , Pages 57-66
Abstract
Recent technological and industrial advances have increased the number of skin burns due to human body exposure to heat in a fire or hot and mechanized environment. In addition, hot environment can produce a strain on a human body leading to discomfort and heat stress and even death. In hot summer days, ...
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Recent technological and industrial advances have increased the number of skin burns due to human body exposure to heat in a fire or hot and mechanized environment. In addition, hot environment can produce a strain on a human body leading to discomfort and heat stress and even death. In hot summer days, many people suffer from heat stroke, dehydration and loss of body fluid. Therefore, the subject of studying thermal energy transport in living tissues is useful for assessing skin burns accurately, better understanding the thermoregulatory system of the body and for developing thermal protection standards. In a hot environment, the most important factor to control the body temperature is evaporation. Accordingly, this study solves one dimensional Pennes’ bio-heat equation by means of backward finite difference formulation. Physical and physiological factors taken into account are: sweat secretion, capillary blood circulation (perfusion), metabolic heat, heat and water exchange with the environment through convection and evaporation. Initially, the model is validated using the work of Zhao et al. Then, the evaporation term is added to the model to study the effect of ambient temperature variation on skin tissue temperature. The results show that thermal disease such as hyperthermia can be expected if uncovered skin is held for a specific time at hot environment. It is observed that increasing ambient temperature causes a shift in the location of the maximum temperature toward the surface of the skin, i.e., the maximum temperature occurs at the depth of about 9 and 7.6 mm of skin surface for ambient temperature of 50 and 60°C, respectively.
Bioheat Transfer
Seyed Alireza Zolfaghari; Mehdi Maerefat; Amir Omidvar
Volume 4, Issue 1 , June 2010, , Pages 13-21
Abstract
Generally, most of the human thermal response models are dependent upon a narrow range of personal/environmental parameters. In other words, the effects of other parameters such as eating foods are not considered in these models. On the other hand, previous studies have indicated that the overall thermal ...
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Generally, most of the human thermal response models are dependent upon a narrow range of personal/environmental parameters. In other words, the effects of other parameters such as eating foods are not considered in these models. On the other hand, previous studies have indicated that the overall thermal condition of the body can be significantly affected by eating cold or hot foods. In the present study, the time-dependent thermal response of the human body is simulated with considering the effect of eating hot/cold food. This simulation is performed by adding an extra term to Gagge’s transient model. In this study, three thermal conditions of the human body (hot, neutral and cold) are considered and the effects of eating hot/cold food are investigated under the mentioned conditions. Results indicate that the effects of eating hot or cold food are not negligible during the eating time and also in a period of time after that. At the neutral condition, the human thermal sensation is more sensitive to hot food than to cold ones. Eating hot food changes the body thermal sensation from neutral to hot. But, eating cold food would not make significant changes in the thermal sensation of the body. Results also show that cold food changes the body core temperature more than hot food. While hot food influences the skin temperature significantly.
Bioheat Transfer
Mehdi Maerefat; Manije Mokhtari Dizaji; Zahra Haddad Soleimani
Volume 3, Issue 3 , June 2009, , Pages 189-197
Abstract
In this paper a comprehensive mathematical model for thermal analysis of liver tissue in thermotherapy of liver cancer by laser is presented. In the present model the diffusion approximation analytical method for radiative heat transfer modeling of heat transfer process in the tissue is used for the ...
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In this paper a comprehensive mathematical model for thermal analysis of liver tissue in thermotherapy of liver cancer by laser is presented. In the present model the diffusion approximation analytical method for radiative heat transfer modeling of heat transfer process in the tissue is used for the first time. Heat transfer modeling in the biological tissue is carried out using Penes model taking into account the influence of thermal and blood perfusion coefficient fluctuations due to temperature changes as well as the effect of lipid melting on temperature distribution through enthalpy method is taken into account. In the present study the tumor is considered as a sphere with thermo-physical properties different with those of healthy tissue. Finally, the obtained non-linear equations are solved using the numerical finite volume method. Temperature distribution at several instants during the thermotherapy is calculated. The comparison of the calculated results with those of experimental results indicate a good agreement between the results. Furthermore, the effects of different parameters such as laser specifications and optic coefficient changes (through proper photopherin injection) on laser-affected area are studied using the present analytical method. These results can help the specialists in order to come upon a safe LITT method for destruction of cancerous tissues without harming the healthy ones.
Bioheat Transfer
Farzan Ghalichi; Sohrab Behnia
Volume 1, Issue 1 , June 2007, , Pages 1-8
Abstract
The methods of focusing ultrasonic waves in order to apply hyperthermia cancer therapy have studied and a transducer capable of focusing waves on cancerous tissues with the aid of its piezoelectricelements has introduced. The amount of absorbed energy was computed by solving numerically the acoustic ...
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The methods of focusing ultrasonic waves in order to apply hyperthermia cancer therapy have studied and a transducer capable of focusing waves on cancerous tissues with the aid of its piezoelectricelements has introduced. The amount of absorbed energy was computed by solving numerically the acoustic pressure equation using Rayleigh-Summerfield Integral, with the intention to determine the optimum spatial array of piezoelectric elements for energy concentration. In order to control the treatment procedure, the numerical solution of Bio-heat Transfer Equation (BHTE), along with the finite-element simulation of thermal energy distribution in a cervix cancerous tissue is considered.
Cardiovascular Biomechanics
Nasser Fatouraee; Mojtaba Gholipour Samarghaveh
Volume 1, Issue 1 , June 2007, , Pages 9-17
Abstract
Blood is one of the vital fluids of the human body. Measurement of its viscosity and other properties is very important in detecting and understanding different cardiovascular diseases. In this study, the blood flow in a concentric cylinder viscometer was simulated numerically. The blood flow patterns ...
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Blood is one of the vital fluids of the human body. Measurement of its viscosity and other properties is very important in detecting and understanding different cardiovascular diseases. In this study, the blood flow in a concentric cylinder viscometer was simulated numerically. The blood flow patterns were analyzed by applying different rotational speed of inner cylinder. Creation of a Couette flow, end effects and suitable rotational speed limit were analyzed. The amount of the torque applied to the inner cylinder which prevents the generation of the Taylor vortices was also predicted. From the obtained results, one can conclude that these vortices were not as important as the end effects were. In order to keep the blood sample temperature within a constant and acceptable range a thermal bath was used. Heat removal rate with different inflow rates of coolant was also predicted numerically.
