Unit Seven: Respiration

1. Unit Seven: Respiration Chapter 39: Physical Principles of Gas Exchange; Diffusion of Oxygen and Carbon Dioxide Through the Respiratory Membrane Guyton and Hall, Textbook of Medical Physiology, 12 edition

2. Physics of Gas Diffusion and Gas Partial Pressure • Molecular Basis of Gas Diffusion- kinetic motion of the molecules • Effect of a Concentration Gradient- net diffusion from areas of high concentration to areas of lower concentration Fig. 39.1

3. Physics of Gas Diffusion and Gas Partial Pressure • Gas Pressures in a Mixture of Gases- “partial pressures of individual gases • Pressure is directly proportional to the concentration of all the gas molecules • Rate of diffusion of each gas is directly proportional to the pressure caused by that gas alone (called the partial pressure)

4. Physics of Gas Diffusion and Gas Partial Pressure • Pressure of Gases Dissolved in Water and Tissues • Solubility Coefficient • Henry’s Law • Diffusion of gases between the alveoli and pulmonary blood • Vapor pressure of water

5. Physics of Gas Diffusion and Gas Partial Pressure • Diffusion of Gases Through Fluids- pressure difference causes net diffusion • Composition of Alveolar Air and Atmospheric Air Are Different

6. Table 39.1 Partial Pressures of Respiratory Gases as They Enter and Leave the Lungs (at Sea Level)

7. Composition (cont.) • Rate at Which Alveolar Air is Renewed by Atmospheric Air Fig. 39.2 Expiration of a gas from an alveolus with successive breaths Fig. 39.3 Rate of removal of excess gas from alveoli

8. Composition (cont.) • Oxygen Concentration and Partial Pressure • in the Alveoli • Oxygen concentration in the alveoli, as well as partial pressure, is controlled by • The rate of absorption of oxygen into the blood • The rate of entry of new oxygen into the lungs by ventilation

9. Composition (cont.) Fig. 39.4 Effect of alveolar ventilation on the alveolar PO2 at two rates of oxygen absorption from the aveoli

10. Composition (cont.) • CO2 Concentration and Partial Pressure in • the Alveoli • Alveolar PCO2 increases directly in proportion • to the rate of carbon dioxide excretion • Alveolar PCO2 decreases in inverse proportion • to alveolar ventilation

11. Composition (cont.) Fig. 39.5 Effect of alveolar ventilation on the alveolar PCO2 at two rates of carbon dioxide excretion from the blood

12. Composition (cont.) • Expired Air is a Combination of Dead Space • Air and Alveolar Air Fig. 39.6

13. Diffusion of Gases Through the Respiratory Membrane • Respiratory Unit- composed of • A respiratory bronchiole • Alveolar ducts • Atria • Alveoli

14. Respiratory Membrane (cont.) Fig. 39.7 Respiratory Unit Fig. 39.7 Surface view of capillaries in an alveolar wall

15. Respiratory Membrane (cont.) • Respiratory Membrane- has the following layers: • Layer of fluid lining the alveolus and containing • surfactant to reduce surface tension • Alveolar membrane (layer of thin epithelial cells) • Epithelial basement membrane • Thin interstitial space between the alveolar and • capillary membranes • Capillary basement membrane (fuses with the • alveolar membrane • f. Capillary endothelial membrane

16. Respiratory Membrane (cont.) Fig. 39.9 Ultrastructure of the alveolar respiratory membrane

17. Respiratory Membrane (cont.) • Factors Affecting Diffusion Rate Through • the Respiratory Membrane • Thickness of the membrane • Surface area of the membrane • Diffusion coefficient of gases • Partial pressure difference of the gas between • the two sides of the membrane

18. Respiratory Membrane (cont.) • Diffusing Capacity of the Membrane- the volume • of gas that will diffuse through the membrane • each minute for a partial pressure difference • of 1 mm Hg • For oxygen, the normal: 21 ml/min/mm Hg • Increases during exercise (better ventilation- • perfusion ratio) • c. Not measured but approx. 20x that of oxygen

19. Respiratory Membrane (cont.) Fig. 39.10 Diffusing capacities for carbon monoxide, oxygen, and carbon dioxide in normal lungs under resting conditions and exercise