Theory and applications of heat transfer in humans /

An authoritative guide to theory and applications of heat transfer in humans' Theory and Applications of Heat Transfer in Humans 2V Set offers a reference to the field of heating and cooling of tissue, and associated damage. The author'a noted expert in the field'presents, in this boo...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Shrivastava, Devashish, 1976- (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken, NJ : Wiley, 2018.
Temas:
Biophysics.
Heat > Transmission.
Human physiology.
Biophysics
Physiologie humaine.
Biophysique.
Chaleur > Transmission.
heat transmission.
SCIENCE > Life Sciences > Biochemistry.
Heat > Transmission
Human physiology
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright; Volume I Contents; Volume II Contents; List of Contributors to Volume I; List of Contributors to Volume II; Preface; Supplementary Material; Volume I; Section I Theory: Physics; Chapter 1 A Generic Thermal Model for Perfused Tissues; 1.1 Introduction; 1.2 Derivation of Generic Bioheat Thermal Models (GBHTMs); 1.2.1 A Two-Compartment Generic Bioheat Transfer Model; 1.2.2 Simplifications; 1.2.3 A Three-Compartment and 'N + 1' Compartment GBHTM; 1.3 Comparing the Two-Compartment GBHTM with Pennes' BHTM.
  • 1.4 Comparing the Predictions of the Two-Compartment GBHTM and Pennes' BHTM with Measured in vivo Temperature Changes during MRI1.5 Summary; Disclaimer; Nomenclature; Subscripts; Greek; References; Chapter 2 Alternate Thermal Models to Predict in vivo Temperatures; 2.1 Introduction; 2.2 Estimating Core Temperature; 2.2.1 Thermal Model; 2.2.2 Example: The Effect of Anesthetics on the Core Temperature Change; 2.3 Estimating Worst-Case in vivo Temperature Change due to a 'Regional' Source Term; 2.3.1 Thermal Model; 2.4 Estimating in vivo Temperature Change due to a 'Local' Source Term.
  • 2.4.1 Thermal Model2.5 Summary; Disclaimer; References; Chapter 3 Thermal Effects of Blood Vessels; 3.1 Introduction; 3.2 Methods; 3.3 Results; 3.4 Discussion; 3.5 Summary; Disclaimer; References; Chapter 4 Generating Blood Vasculature for Bioheat Computations; 4.1 Introduction; 4.2 Method; 4.2.1 Assumptions and Framework of Method; 4.2.2 Model Inputs: Geometry and Physics of a Region; 4.2.3 Model Output: Geometry and Physics of a Vasculature; 4.2.4 Constraints and Criteria; 4.2.5 Iterative Generation of a Vasculature; 4.2.6 Using Tree Structures for Computational Efficiency; 4.3 Examples.
  • 4.3.1 Geometry and Flow Parameters4.3.2 Growing a Vasculature; 4.3.3 Capillary Bed; 4.3.4 Obstructions; 4.3.5 Finger; 4.4 Summary; Disclaimer; References; Chapter 5 Whole-Body Human Computational Models and the Effect of Clothing; 5.1 Introduction; 5.2 The Clothing-Environment Relationship for Firefighting; 5.2.1 Properties of Protective Garments Worn by Firefighters; 5.2.2 Metabolic Heat Generation during Firefighting; 5.2.3 Ambient Conditions and Exposure Time; 5.2.4 Analysis of Heat Strain while Wearing Protective Clothing.
  • 5.3 A Human Thermal Model for Analyzing Thermal Stress during Firefighting5.3.1 Physiological Variables; 5.3.2 Validation of the Model; 5.3.3 Modeling Ambient Conditions; 5.3.4 Heat Load Imposed on Individuals by Fire; 5.4 Results; 5.4.1 Analysis of Thermal Injury of an Unprotected Individual from a Flash Fire; 5.4.2 Analysis of the Effect of Heat Stress on Firefighters; 5.5 Discussion and Conclusion; Disclaimer; References; Chapter 6 Models of the Cardiovascular System; 6.1 Purposes; 6.2 History; 6.3 Similitude and Dimensional Analysis; 6.3.1 Geometric Similitude; 6.3.2 Kinematic Similitude.

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