BIOPHYSICAL PRINCIPLES OF HEMODYNAMICS -- BIOPHYSICAL PRINCIPLES OF HEMODYNAMICS -- CONTENTS -- PREFACE -- Chapter 1 INTRODUCTION -- Chapter 2 LAMINAR CURRENT IN THE SMOOTH RIGID TUBES -- 2. 1. CONTINUITY EQUATION -- 2.2. BERNOULLI'S EQUATION -- 2.3. POISEUILL'S LAW -- 2.4. THE STREAMING OF FLUID THROUGH THE TUBES OF ALTERNATING SECTION AND RAMIFIED TUBES -- 2.4.1. The Gradient of Pressure in a Cylindrical Tube -- 2.4.2. The Resistance of the Tubes of Variable Section and Ramified Tubes -- 2.4.3. The Distribution of Pressure and Bloodstream Speed in the System of Blood Circulation -- Chapter 3 RHEOLOGICAL BLOOD FEATURES -- 3.1. THE FAREUS-LINDKWIST EFFECT -- Chapter 4 SHORT REVIEW OF EXISTING DIFFERENTIAL MODELS OF FLOW OF BLOOD IN LARGE BLOOD VESSELS -- 4.1. CONTINUITY EQUATION IN THE ELASTIC TUBE -- 4.1.1. Vectorial Form of Continuity Equation in Elastic Tube -- 4.2. IMPULSE EQUATION -- 4.3. REGISTRATION OF VESSEL'S ELASTICITY IN IMPULSE EQUATION -- Chapter 5 O. FRANC'S INTEGRAL MODEL OF BLOOD CIRCULATION -- 5.1. LINEAR ONE CAMERA MODEL -- 5.2. MULTIPLE CAMERA AND NONLINEAR MODELS OF ELASTIC RESERVOIR -- Chapter 6 RESTRICTIONS FOR THE USAGE OF BERNOULLI'S LAW FOR ELASTIC BLOOD VESSELS -- Chapter 7 STREAM OF NONVISCOUS FLUID IN TUBES WITH ELASTIC WALLS -- 7.1. HYDRODYNAMICS OF PULSE STREAM IN ELASTIC BLOOD VESSEL -- 7.2. THE IMPULSE'S EQUATION FOR ELASTIC BLOOD VESSEL -- 7.3. THE SPEED OF WAVE PRESSURE SPREAD (PULSE WAVE IN BLOOD VESSEL) -- 7.4. THE ROLE OF BLOOD VESSEL WALL'S ELASTICITY IN THE IMPULSE'S EQUATION -- 7.4.1. Bernoulli's Equation for Elastic Tube -- 7.5. ABOUT AN OPPORTUNITY OF THE DECISION OF THE IMPULSE EQUATION IN THE ELASTIC VESSEL AS TRAVELING WAVES -- 7.6. PULSE WAVE -- 7.6.1. Pulse Wave Modeling by Schrödinger's Non-Linear Equation -- 7.6.2. Modeling of Pulse Wave by Korteweg and De Vries Equation.

7.7. FLUTTER IN BLOOD VESSELS -- 7.7.1. Clinical Method of Arterial Pressure Measurement -- 7.7.2. Hooke's Law for Elastic Tube -- 7.7.3. Auto-oscillating (Fluttering) Regimen of Stream in Elastic Tube -- 7.7.4. Modeling of Appearance of Korotkov's Tones -- 7.8. SHOCKING WAVES IN THE VASCULAR SYSTEM -- 7.8.1. Comparative Characteristics of Shocking Waves of Different Form in Blood Vessel -- Chapter 8 STREAMING OF VISCOSITY FLUID IN ELASTIC BLOOD VESSELS -- 8.1. VISCOSITY STREAM IN CURRENTS NON-RESTRICTED BY ELASTIC SURFACE -- 8.2. INFLUENCE OF BLOOD VISCOSITY ON HYDRODYNAMICS OF STREAM IN VESSELS -- 8.3. PULSE BLOODSTREAM IN THE VESSEL -- 8.4. USE OF STRESS TENSOR FOR THE ANALYSIS OF LAMINAR CURRENT OF THE FLUID -- Chapter 9 SOME QUESTIONS OF THEORY OF REGULATION OF ARTERIAL BLOOD VESSELS -- 9.1. STRUCTURAL-FUNCTIONAL ORGANIZATION OF SYSTEM OF REGULATION OF ARTERIAL BLOOD VESSELS -- 9.2. TASKS OF REGULATORY FUNCTION OF ARTERIAL BLOOD VESSELS -- 9.3. FUNCTIONING OF SYSTEM OF REGULATION OF ARTERIAL BLOOD VESSELS -- 9.4. ESSENTIAL (PRIMARY) ARTERIAL HYPERTENSION -- Chapter 10 TURBULENT FLOW IN BLOOD VESSELS -- 10.1. TURBULENCE MODEL FOR BLOODSTREAM IN AORTA -- 10.2. DEGENERATION OF TURBULENCE IN AORTA -- 10.3. ROLE OF TURBULENCE IN VASCULAR SYSTEM -- Chapter 11 СONCLUSION -- Chapter 12 LITERATURE -- ANNOTATION -- INDEX.