Biofluid Mechanics [recurso electrónico] : an Introduction to Fluid Mechanics, Macrocirculation, and Microcirculation.

Por: Rubenstein, DavidColaborador(es): Yin, Wei | Frame, Mary DTipo de material: TextoTextoSeries Academic Press series in biomedical engineeringDetalles de publicación: Burlington : Elsevier Science, 2011Descripción: 1 online resource (829 pages)Tipo de contenido: text Tipo de medio: computer Tipo de portador: online resourceISBN: 9780123813848 (electronic bk.); 0123813840 (electronic bk.)Tema(s): Hemodynamics | Biomedical engineering | Body Fluids -- physiology | Rheology | Biomechanics | Blood Circulation -- physiology | Hemodynamics -- physiology | Biomedical engineering -- Congresses | Body fluid flow -- Congresses | Hemodynamics -- Congresses | Rheology (Biology) -- Congresses | Zoology | Natural history | Science | NATURE -- Animals -- Mammals | SCIENCE -- Life Sciences -- Zoology -- Mammals | Biomedical engineering | HemodynamicsGénero/Forma: Electronic books. | Electronic books.Formatos físicos adicionales: Print version:: Biofluid Mechanics : An Introduction to Fluid Mechanics, Macrocirculation, and Microcirculation.Clasificación CDD: 599.01/01/53 Clasificación LoC:QP105Recursos en línea: Libro electrónico ScienceDirectTexto
Contenidos:
Cover image; Table of Contents; Front-matter; Copyright; Preface; Chapter 1. Introduction; 1.1. Note to Students About the Textbook; 1.2. Biomedical Engineering; 1.3. Scope of Fluid Mechanics; 1.4. Scope of Biofluid Mechanics; 1.5. Dimensions and Units; Chapter 2. Fundamentals of Fluid Mechanics; 2.1. Fluid Mechanics Introduction; 2.2. Fundamental Fluid Mechanics Equations; 2.3. Analysis Methods; 2.4. Fluid as a Continuum; 2.5. Elemental Stress and Pressure; 2.6. Kinematics: Velocity, Acceleration, Rotation and Deformation; 2.7. Viscosity; 2.8. Fluid Motions; 2.9. Two-Phase Flows.
2.10. Changes in the Fundamental Relationships on the Microscale2.11. Fluid Structure Interaction; Chapter 3. Conservation Laws; 3.1. Fluid Statics Equations; 3.2. Buoyancy; 3.3. Conservation of Mass; 3.4. Conservation of Momentum; 3.5. Momentum Equation with Acceleration; 3.6. The First and Second Laws of Thermodynamics; 3.7. The Navier-Stokes Equations; 3.8. Bernoulli Equation; Chapter 4. The Heart; 4.1. Cardiac Physiology; 4.2. Cardiac Conduction System/Electrocardiogram; 4.3. The Cardiac Cycle; 4.4. Heart Motion; 4.5. Heart Valve Function; 4.6. Disease Conditions.
Chapter 5. Blood Flow in Arteries and Veins5.1. Arterial System Physiology; 5.2. Venous System Physiology; 5.3. Blood Cells and Plasma; 5.4. Blood Rheology; 5.5. Pressure, Flow, and Resistance: Arterial System; 5.6. Pressure, Flow, and Resistance: Venous System; 5.7. Wave Propagation in Arterial Circulation; 5.8. Flow Separation at Bifurcations and at Walls; 5.9. Flow Through Tapering and Curved Channels; 5.10. Pulsatile Flow and Turbulence; 5.11. Disease Conditions; Chapter 6. Microvascular Beds; 6.1. Microcirculation Physiology; 6.2. Endothelial Cell and Smooth Muscle Cell Physiology.
6.3. Local Control of Blood Flow6.4. Pressure Distribution Throughout the Microvascular Beds; 6.5. Velocity Distribution Throughout the Microvascular Beds; 6.6. Interstitial Space Pressure and Velocity; 6.7. Hematocrit/Fahraeus-Lindquist Effect/Fahraeus Effect; 6.8. Plug Flow in Capillaries; 6.9. Characteristics of Two-phase Flow; 6.10. Interactions Between Cells and the Vessel Wall; 6.11. Disease Conditions; Chapter 7. Mass Transport and Heat Transfer in the Microcirculation; 7.1. Gas Diffusion; 7.2. Glucose Transport; 7.3. Vascular Permeability; 7.4. Energy Considerations.
7.5. Transport through Porous Media7.6. Microcirculatory Heat Transfer; 7.7. Cell Transfer During Inflammation/White Blood Cell Rolling and Sticking; Chapter 8. The Lymphatic System; 8.1. Lymphatic Physiology; 8.2. Lymph Formation; 8.3. Flow Through the Lymphatic System; 8.4. Disease Conditions; Chapter 9. Flow in the Lungs; 9.1. Lung Physiology; 9.2. Elasticity of the Lung Blood Vessels and Alveoli; 9.3. Pressure-Volume Relationship for Air Flow in the Lungs; 9.4. Oxygen/Carbon Dioxide Diffusion; 9.5. Oxygen/Carbon Dioxide Transport in the Blood; 9.6. Compressible Fluid Flow.
Resumen: Both broad and deep in coverage, Rubenstein shows that fluid mechanics principles can be applied not only to blood circulation, but also to air flow through the lungs, joint lubrication, intraocular fluid movement and renal transport. Each section initiates discussion with governing equations, derives the state equations and then shows examples of their usage. Clinical applications, extensive worked examples, and numerous end of chapter problems clearly show the applications of fluid mechanics to biomedical engineering situations. A section on experimental techniques provides a springboard for.
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Existencias
Tipo de ítem Biblioteca actual Colección Signatura Copia número Estado Fecha de vencimiento Código de barras
Libro Electrónico Biblioteca Electrónica
Colección de Libros Electrónicos QP105 (Browse shelf(Abre debajo)) 1 No para préstamo 380653-2001

Cover image; Table of Contents; Front-matter; Copyright; Preface; Chapter 1. Introduction; 1.1. Note to Students About the Textbook; 1.2. Biomedical Engineering; 1.3. Scope of Fluid Mechanics; 1.4. Scope of Biofluid Mechanics; 1.5. Dimensions and Units; Chapter 2. Fundamentals of Fluid Mechanics; 2.1. Fluid Mechanics Introduction; 2.2. Fundamental Fluid Mechanics Equations; 2.3. Analysis Methods; 2.4. Fluid as a Continuum; 2.5. Elemental Stress and Pressure; 2.6. Kinematics: Velocity, Acceleration, Rotation and Deformation; 2.7. Viscosity; 2.8. Fluid Motions; 2.9. Two-Phase Flows.

2.10. Changes in the Fundamental Relationships on the Microscale2.11. Fluid Structure Interaction; Chapter 3. Conservation Laws; 3.1. Fluid Statics Equations; 3.2. Buoyancy; 3.3. Conservation of Mass; 3.4. Conservation of Momentum; 3.5. Momentum Equation with Acceleration; 3.6. The First and Second Laws of Thermodynamics; 3.7. The Navier-Stokes Equations; 3.8. Bernoulli Equation; Chapter 4. The Heart; 4.1. Cardiac Physiology; 4.2. Cardiac Conduction System/Electrocardiogram; 4.3. The Cardiac Cycle; 4.4. Heart Motion; 4.5. Heart Valve Function; 4.6. Disease Conditions.

Chapter 5. Blood Flow in Arteries and Veins5.1. Arterial System Physiology; 5.2. Venous System Physiology; 5.3. Blood Cells and Plasma; 5.4. Blood Rheology; 5.5. Pressure, Flow, and Resistance: Arterial System; 5.6. Pressure, Flow, and Resistance: Venous System; 5.7. Wave Propagation in Arterial Circulation; 5.8. Flow Separation at Bifurcations and at Walls; 5.9. Flow Through Tapering and Curved Channels; 5.10. Pulsatile Flow and Turbulence; 5.11. Disease Conditions; Chapter 6. Microvascular Beds; 6.1. Microcirculation Physiology; 6.2. Endothelial Cell and Smooth Muscle Cell Physiology.

6.3. Local Control of Blood Flow6.4. Pressure Distribution Throughout the Microvascular Beds; 6.5. Velocity Distribution Throughout the Microvascular Beds; 6.6. Interstitial Space Pressure and Velocity; 6.7. Hematocrit/Fahraeus-Lindquist Effect/Fahraeus Effect; 6.8. Plug Flow in Capillaries; 6.9. Characteristics of Two-phase Flow; 6.10. Interactions Between Cells and the Vessel Wall; 6.11. Disease Conditions; Chapter 7. Mass Transport and Heat Transfer in the Microcirculation; 7.1. Gas Diffusion; 7.2. Glucose Transport; 7.3. Vascular Permeability; 7.4. Energy Considerations.

7.5. Transport through Porous Media7.6. Microcirculatory Heat Transfer; 7.7. Cell Transfer During Inflammation/White Blood Cell Rolling and Sticking; Chapter 8. The Lymphatic System; 8.1. Lymphatic Physiology; 8.2. Lymph Formation; 8.3. Flow Through the Lymphatic System; 8.4. Disease Conditions; Chapter 9. Flow in the Lungs; 9.1. Lung Physiology; 9.2. Elasticity of the Lung Blood Vessels and Alveoli; 9.3. Pressure-Volume Relationship for Air Flow in the Lungs; 9.4. Oxygen/Carbon Dioxide Diffusion; 9.5. Oxygen/Carbon Dioxide Transport in the Blood; 9.6. Compressible Fluid Flow.

9.7. Disease Conditions.

Both broad and deep in coverage, Rubenstein shows that fluid mechanics principles can be applied not only to blood circulation, but also to air flow through the lungs, joint lubrication, intraocular fluid movement and renal transport. Each section initiates discussion with governing equations, derives the state equations and then shows examples of their usage. Clinical applications, extensive worked examples, and numerous end of chapter problems clearly show the applications of fluid mechanics to biomedical engineering situations. A section on experimental techniques provides a springboard for.

Includes bibliographical references and index.

Print version record.

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