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External Gas Transport Chapters 20 & 21 Respiration The process of acquiring oxygen and releasing carbon dioxide.

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Presentation on theme: "External Gas Transport Chapters 20 & 21 Respiration The process of acquiring oxygen and releasing carbon dioxide."— Presentation transcript:

1

2 External Gas Transport Chapters 20 & 21

3 Respiration The process of acquiring oxygen and releasing carbon dioxide

4 Why do animals require oxygen? Aerobic respiration –C 6 H 12 O 6 + 6O 2  6CO 2 + 6H 2 O –Enough Energy for 30 ATP Anaerobic respiration –C 6 H 12 O 6  2C 3 H 6 O 3 –Enough Energy for 2 ATP All known metazoans require oxygen

5 Why do animals need to release carbon dioxide? CO 2 tends to react with water CO 2 + H 2 O  H 2 CO 3  H + + HCO 3 -  2H + + CO 3 -  [H + ],  pH Low pH’s can disrupt physiological function (e.g., enzyme activity)

6 Air Composition (Dry Air): –May vary in some environments (burrows, soil) –Water vapor can also alter this composition

7 Principles of Gas Diffusion in Air Gases Exert Pressures –Atmospheric Pressure (760 mmHg (1 atm) at sea level) The relationship between the concentration of a gas and pressure is described in the Ideal Gas Law PV = nRT –P = pressure –V = volume –n = moles of gas –R = universal gas constant (8.314 J/mol*°K) –T = temperature (°K)

8 Principles of Gas Diffusion Dalton’s Law of Partial Pressures –the total pressure exerted by a gas mixture is the sum of individual pressures exerted by each gas –e.g. P O2 = 20.95% * 760 mmHg = 159 mmHg Diffusion (for Gases) –movement of a gas from an area of high partial pressure to one of low partial pressure –Movement of a gas can occur against a concentration gradient as long it flows along the partial pressure gradient

9 Factors Influencing Gas Diffusion in Air –J = net rate of diffusion between point 1 and point 2 –K = Krogh’s diffusion coefficient (depends on medium permeability, temperature, and the specific gas being transported) –P 1 and P 2 = particle concentration at points 1 and 2 –X = distance between points 1 and 2 J = K × P 1 – P 2 X

10 Diffusion rate increases with… Bigger differences in concentration Shorter diffusion differences Greater medium permeability Higher temperatures

11 Water Gases are soluble in water Amount of a gas in water depends on: –solubility of the gas –the pressure of the gas in the gas phase –temperature –presence of other solutes

12 Solubility Measured as the solubility coefficient (  ) –volume of gas dissolved in 1 L when the pressure of the gas = 1 atm Different gases have different solubilities:

13 Pressure Amount of gas dissolved is proportional to the pressure (tension) of the gas Henry’s Law: –V g =  (P g /760)*V H2O V g = volume of gas dissolved (ml) P g = pressure of the gas (mmHg) V H2O = volume of water (L)  = solubility coefficient

14 Temperature and Other Solutes Temperature –  temperature,  solubility of gases –Opposite of solid solutes Other Solutes –  [solid solutes],  solubility of gases –[other gases] does not affect solubility

15 Temperature and Other Solutes

16 Partial Pressures in Water Amt of gas in water corresponds to a specific gas pressure in the gas phase Gas Tension –pressure of a gas in an atmosphere with which the solution is in equilibrium

17 Air vs. Water Air contains more O 2 than water (30x) Air is less dense than water (1/800th) –easier to move over respiratory surfaces –less energy expenditure Respiratory gases diffuse much more quickly in air than in water (~10,000x greater for O 2 ) Use of air can lead to water loss through evaporation

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