I Physical Principles of Gas Exchange

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Respiratory Gases Exchange Dr Badri Paudel, M.D. 2 I Physical Principles of Gas Exchange 3 Partial pressure The pressure exerted by each type of gas in a mixture Diffusion of gases through liquids Concentration of a gas in a liquid is determined by its partial pressure and its solubility Partial Pressures of Gases Basic Composition of Air 79% Nitrogen 21 % Oxygen ~ % Carbon Dioxide In a mixture of gases, each gas exerts a partial pressure proportional to its mole fraction. Total Pressure = sum of the partial pressures of each gas Total Pressure (at sea level) P barometric = 76 mm Hg Pgas = Pb x Fgas PN = 76 x.79 = 6.4 mm Hg P 2 = 76 x.21 = 159.6 mm Hg 76 mm Hg 5 6 P b P b 1

7 8 Ficks Law! Amount of gas passing through a membrane is directly proportional to the area of the membrane, diffusivity of the gas and pressure deference! but inversely prpertional to thickness of the membrane P 1 gas AREA 14 m 2 Fick s Law flux V gas = A x K P2 T.5 m X (P 1 P 2 ) T K = Sol. Mol. Wt. 9 14/.5 = 28,, 1 Diffusion diffusion dependent on perfusion and the partial pressure (pp) exerted by each gas gases diffuse from area of conc. (pp) to conc. (pp)! concentration pp of gas diffusion! CO 2 more soluble than O 2, therefore it diffuses faster 11 12 2

Diffusion: Blood Transit time in the Alveolus mm Hg 1 45 4 Alveolus Blood capillary Time for exchange P O2 Saturated very quickly Reserve diffusive Capacity of the lung P CO2 II Gas exchange in the lung and in the tissue Time.75 sec 13 14 Oxygen and Carbon Dioxide Diffusion Gradients Oxygen Moves from alveoli into blood. Blood is almost completely saturated with oxygen when it leaves the capillary P 2 in blood decreases because of mixing with deoxygenated blood Oxygen moves from tissue capillaries into the tissues Carbon dioxide Moves from tissues into tissue capillaries Moves from pulmonary capillaries into the alveoli Diffusion Gradients of Respiratory Gases at Sea Level Partial pressure (mmhg) % in Dry Alveolar Venous Diffusion Gas dry air air air blood gradient Total 1. 76. 76 76 H 2 O.. 47 47 O 2 2.93 159.1 15 4 65 CO 2.3.2 4 46 6 N 2 79.4 6.7 569 573 NB. CO 2 is ~2x more soluble than O 2 in blood => large amounts move into & out of the blood down a relatively small diffusion gradient. 15 16 PO 2 and PCO 2 in Blood III. A-a gradient, the efficiency of the gas exchange in alveoli 17 3

What is an A - a gradient? The DIFFERENCE between: Oxygen Content in Alveolus Gas (measured during exhalation) Oxygen Content in arterial blood (equivalent to that leaving lungs) In a healthy person, what would you expect the A - a to be? No difference, greater than, or less than Normal: A a, up to ~ 1 mm Hg, varies with age Factors contributing to A - a Gradient 1. Blood Shunts 2. Matching 19 2 IV Factors Affecting the Gas Diffusion in the Lung 21 1. The Properties of the Gas 1) Molecular weight. Diffusion rate is inversely proportional to the square root of the molecular weight 2) Temperature 3) Solubility in water Each gas has a specific solubility O 2 Solubility coefficient =.3 ml 2 /1 ml Blood C 2 =.6 ml/1 ml Blood (x 2 of 2 ) mm HG 1 45 4 P O2 Saturated very quickly Reserve diffusive Capacity of the lung P CO2 Time.75 sec 2. Partial Pressure of the Gases 1) Alveoli ventilation 2) Blood perfusion in the lung capillary 3) Speed of the chemical reaction The slow speed of the chemical reaction HCO 3 - + H + ----- H 2 CO 3 ---H 2 O + CO 2 reduces the CO 2 exchange in the lung. So, during the gas exchange in the external respiration, the exchange of CO 2 is a little lower than that of O 2. 23 24 4

3. Properties of the Lung 1) Area of the respiratory membrane 2) Distance of the diffusion 3) V A /Q c V Pulmonary Diffusion Capacity Concept: The ability of the respiratory membrane to exchange a gas between the alveoli and the pulmonary blood defined as the volume of a gas that diffuses through the membrane each minute for a pressure of 1 mmhg. D L = V/(P A P C ) V is a gas that diffuses through the membrane each minute, P A is the average partial pressure of a gas in the air of alveoli, P C is the average partial pressure of a gas in the blood of pulmonary capillary. 25 26 Factors Affecting the D L 1. Body posture 2. Body height and weight VI Factors Affecting the Gas Exchange 3. Exercise 4. Pulmonary diseases 27 28 29 3 5

Diffusivity! The membrane character is lost due to fibrosis in diseases like asbestosis, silicosis etc which affect the solubility of a gas in the membrane and their diffusivity is also affected. 31 32 The pressure gradient! During increased ventilation/o 2 inhalation P A2 increases leading to increased exchange of 2! Hypoventilation, high altitude-- P A2 decreases Ventilation/perfusion ratio! If perfusion remains normal and ventilation is decresed- shunt! If perfusion is decreased or absent and ventilation is normal dead space.! During emphysema V/Q ration is abnormal leading to abnormal gas exchange 33 34 Shunt! It dilutes the oxygenated blood but don t hamper the gas exchange.! Normally some blood is shunted via bronchial vessels, is 1% of cardiac output. Some amount of blood may remain unoxygenated which have passed via underventilated alveoli! Arterial PaO2 is 95 mmhg while pulmonary capillary has 1 mmhg Reaction time! time required for the chemical reactions to occur in blood in relation to gas exchange. Eg 2 to combine with Hb, while CO2 to evolve HCO3 -! time required by the gases to move also influences the gas transfer eg O2 plasma RBC memebrane-inside RBC and Then Hb. 35 36 6

Perfusion limited transfer! If there is more perfusion there will be more transfer is true only if gases whose partial pressure in blood rises quickly and the presure gradient is lost.! Eg N 2 O transfer will only stop unless the blood is saturated with N 2 O is replaced by continuous perfusion.! This will depend on the perfusion Diffusion related transfer! Its true for the gases whose partial pressure in blood doesn t rise, so the pressure gradient remains.! CO on entering in blood combines quickly with Hb and practically no CO remains in dissolved state.! Amount of CO Transferred depends on its rate of diffusion. 37 38 Diffusion limitation vs. perfusion limitation of gas transfer Diffusion limitation vs. perfusion limitation of gas transfer Start of capillary End of capillary Partial Pressure Start of capillary N 2 O ALVEOLAR End of capillary P A = P C = No more transfer = perfusion limitation.25.5.75 Partial Pressure ALVEOLAR.25.5.75 Time in capillary, sec CO P A > P C when blood Leaves capillary. No more transfer = Diffusion limitation Time in capillary, sec 39 4 Diffusion limitation vs. perfusion limitation of gas transfer Start of capillary End of capillary ALVEOLAR Perfusion limitation Partial Pressure O 2 (normal) O 2 (abnormal) N 2 O CO.25.5.75 Time in capillary, sec Diffusion limitation 41 42 7

Thank You! 43 8

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