A mathematical model of rat cortical collecting duct: determinants of the transtubular potassium gradient

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A mathematical model of rat cortical collecting duct: determinants of the transtubular potassium gradient

Alan M. Weinstein

Department of Physiology and Biophysics, Weill Medical College of Cornell University, New York, New York 10021

In assessing disorders of potassium excretion, urine composition is used to calculate the transtubular gradient (TTKG), asan estimate of tubule fluid concentration, at a point when thefluid was last isotonic to plasma, namely, within the corticalcollecting duct (CCD). A mathematical model of the CCD has beendeveloped, consisting of principal cells and $alpha$ - and $beta$ -intercalatedcells, and which includes Na⁺, K⁺, Cl, HCO, CO₂, H₂CO₃, phosphate, ammonia,and urea. Parameters have been selected to achieve fluxes andpermeabilities compatible with data obtained from perfusion studiesof rat CCD under the influence of both antidiuretic hormone andmineralocorticoid. Both epithelial (flat sheet) and tubule modelshave been configured, and model calculations have focused on thedeterminants of the TTKG. Using the epithelial model, luminalK⁺ concentrations can be computed at which K⁺ secretion ceases (0-flux equilibrium), and this luminal concentrationderives from the magnitude of principal cell peritubular uptakeof K⁺ via the Na-K-ATPase, relative to principal cell peritubular membraneK⁺ permeability. When the model is configured as a tubule and examinedin the context of conditions in vivo, osmotic equilibration ofluminal fluid produces a doubling of the initial K⁺ concentration, which, depending on delivered load, may be substantiallygreater than the zero-flux equilibrium value. Under such circumstances,the CCD will be a site for K⁺ reabsorption, although the relatively low permeability ensuresthat this reabsorptive flux is likely to be small. Osmotic equilibrationmay also raise luminal NH₃ concentrations well above those incortical blood. In this situation, diffusive reabsorption of NH₃provides a mechanism for base reclamation without the metaboliccost of active protonsecretion.

distal nephron; aldosterone; urine acidification; ammonia transport

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				J. J. Grantham and D. P. Wallace Return of the secretory kidney Am J Physiol Renal Physiol, January 1, 2002; 282(1): F1 - F9. [Abstract] [Full Text] [PDF]