Carbon Dioxide Transport and Carbonic Anhydrase in Blood and Muscle

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Carbon Dioxide Transport and Carbonic Anhydrase in Blood and Muscle

Cornelia Geers and Gerolf Gros

Zentrum Physiologie, Medizinische Hochschule, Hannover, Germany

Geers, Cornelia and Gerolf Gros. Carbon Dioxide Transport and Carbonic Anhydrase in Blood and Muscle. Physiol. Rev. 80: 681-715, 2000.CO₂ produced within skeletal muscle has to leave the body finally via ventilation by the lung. To get there, CO₂ diffusesfrom the intracellular space into the convective transport mediumblood with the two compartments, plasma and erythrocytes. Withinthe body, CO₂ is transported in three different forms: physicallydissolved, as HCO₃, or as carbamate. The relative contribution of these three formsto overall transport is changing along this elimination pathway.Thus the kinetics of the interchange have to be considered. Carbonicanhydrase accelerates the hydration/dehydration reaction betweenCO₂, HCO₃, and H⁺. In skeletal muscle, various isozymes of carbonic anhydrase arelocalized within erythocytes but are also bound to the capillarywall, thus accessible to plasma; bound to the sarcolemma, thusproducing catalytic activity within the interstitial space; andassociated with the sarcoplasmic reticulum. In some fiber types,carbonic anhydrase is also present in the sarcoplasm. In exercisingskeletal muscle, lactic acid contributes huge amounts of H⁺ and by these affects the relative contribution of the three formsof CO₂. With a theoretical model, the complex interdependenceof reactions and transport processes involved in CO₂ exchangewasanalyzed.

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