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Preface; Contents; Part I: Gases, Bubbles and Surroundings; 1: Perfect Coffee and Oxygen Cylinders: The Ideal Gas Law; 1.1 A Delicious Aroma... and a Nauseating Stench; 1.2 Ideal Gas Law; 1.2.1 Boyle's Law; 1.2.2 First Law of Gay-Lussac (or Charles's Law); 1.2.3 Second Law of Gay-Lussac (or, Simply, Gay-Lussac's Law); 1.2.4 Avogadro's Law; 1.2.5 Dalton's Law; 1.3 Calculating the Duration of an Oxygen Cylinder; 1.4 Decompression Illness and Hyperbaric Therapy; References; 2: Boats, Balloons, and Air Bubbles: Archimedes' Principle
2.1 Archimedes' Principle: Gravity Not Always Makes You Fall2.2 The Anesthesiologist and Archimedes' Principle; References; 3: Air Bubbles in the Blood Sample: Better or Worse Oxygenation? Dalton's Law and Fick's Law; 3.1 Dalton's Law: When You Do the Math, It All Adds Up!; 3.2 Down the Slope: Fick's Law; 3.3 Air Bubbles and Blood Gas Analysis; References; 4: Cold, Sparkling Drinks, and Blood Gas Analysis: Henry's Law; 4.1 The Physics in a Soda Bottle: Henry's Law; 4.2 Acid-Base Management During Cardiopulmonary Bypass; 4.3 Pathophysiology and Treatment of Decompression Sickness
5.3.4 Air EmbolismReferences; Part II: Fluids in Motion: Masks, Tubes, and Hemodynamics; 6: The Venturi Mask Works (In Part) Like an Airplane: Continuity Equation and Bernoulli's Theorem; 6.1 Garden Hoses and Heart Valve Stenosis: Continuity Equation; 6.2 How Does an Airplane Fly? Bernoulli's Theorem; 6.2.1 And Now...Let This Plane Fly!; 6.3 Continuity and Bernoulli's Equations Work Together in a Venturi Mask; References; 7: From Tubes and Catheters to the Basis of Hemodynamics: The Hagen-Poiseuille Equation; 7.1 Real Fluids Flow in a Different Way: Viscosity and Hagen-Poiseuille Equation
7.1.1 Viscosity7.1.2 Hagen-Poiseuille Equation; 7.2 Tubes and Catheters: Some Implications of Hagen-Poiseuille Equation; 7.3 Hagen-Poiseuille Equation and Hemodynamics; References; Part III: Hemodynamic Monitoring; 8: Toothpaste, Sea Deeps, and Invasive Pressure Monitoring: Stevin's Law and Pascal's Principle; 8.1 Fluids at Rest: Stevin's Law and Pascal's Principle; 8.1.1 Under the Sea: Stevin's Law; 8.1.2 Push, Squeeze, and Lift: Pascal's Principle; 8.2 Invasive Pressure Monitoring; 8.2.1 Leveling: How Important Is the Difference?
2.1 Archimedes' Principle: Gravity Not Always Makes You Fall2.2 The Anesthesiologist and Archimedes' Principle; References; 3: Air Bubbles in the Blood Sample: Better or Worse Oxygenation? Dalton's Law and Fick's Law; 3.1 Dalton's Law: When You Do the Math, It All Adds Up!; 3.2 Down the Slope: Fick's Law; 3.3 Air Bubbles and Blood Gas Analysis; References; 4: Cold, Sparkling Drinks, and Blood Gas Analysis: Henry's Law; 4.1 The Physics in a Soda Bottle: Henry's Law; 4.2 Acid-Base Management During Cardiopulmonary Bypass; 4.3 Pathophysiology and Treatment of Decompression Sickness
5.3.4 Air EmbolismReferences; Part II: Fluids in Motion: Masks, Tubes, and Hemodynamics; 6: The Venturi Mask Works (In Part) Like an Airplane: Continuity Equation and Bernoulli's Theorem; 6.1 Garden Hoses and Heart Valve Stenosis: Continuity Equation; 6.2 How Does an Airplane Fly? Bernoulli's Theorem; 6.2.1 And Now...Let This Plane Fly!; 6.3 Continuity and Bernoulli's Equations Work Together in a Venturi Mask; References; 7: From Tubes and Catheters to the Basis of Hemodynamics: The Hagen-Poiseuille Equation; 7.1 Real Fluids Flow in a Different Way: Viscosity and Hagen-Poiseuille Equation
7.1.1 Viscosity7.1.2 Hagen-Poiseuille Equation; 7.2 Tubes and Catheters: Some Implications of Hagen-Poiseuille Equation; 7.3 Hagen-Poiseuille Equation and Hemodynamics; References; Part III: Hemodynamic Monitoring; 8: Toothpaste, Sea Deeps, and Invasive Pressure Monitoring: Stevin's Law and Pascal's Principle; 8.1 Fluids at Rest: Stevin's Law and Pascal's Principle; 8.1.1 Under the Sea: Stevin's Law; 8.1.2 Push, Squeeze, and Lift: Pascal's Principle; 8.2 Invasive Pressure Monitoring; 8.2.1 Leveling: How Important Is the Difference?