Structural organization of the renal medulla: comparative and functional aspects

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Structural organization of the renal medulla: comparative and functional aspects

W. Kriz

The renal medulla develops very differently among species, being more prominent in those with a high urinary concentrating capacity. Attempts to correlate structure and function must consider loops of Henle, collecting ducts, vessels, interstitium, and pelvis. Two types of loops of Henle, long and short, are distinguished. Numerical relationships between both differ among species. Based on the epithelial lining a short loop consists of a thick descending limb (pars recta of proximal tubule), a thin descending limb, and a thick ascending limb. Long loops, in addition, have a thin ascending limb; their descending thin limbs are different from those of short loops and are site of considerable interspecies differences. Collecting ducts form in the cortex by joining several nephrons. Patterns with and without arcade formation are distinguished. On entering inner medulla, collecting ducts fuse successively. Collecting duct epithelium consists of principal and intercalated cells whose individual functions are subject to debate. Blood vessels are arranged in a very strict pattern reflecting that, in addition to nourishment, unique requirements in maintaining the corticomedullary osmotic gradient are to be met. Ultrastructural organization of medullary vessels is less specific compared to cortical vessels. Two types of renal medulla are distinguished. The simple type has vascular bundles consisting only of de- and ascending vasa recta; in the complex type, descending thin limbs of short loops are also integrated into vascular bundles. Functional implications of this difference are considerable. Striking interspecies differences also occur in the renal pelvis.

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				X. Wang, S. R. Thomas, and A. S. Wexler Outer medullary anatomy and the urine concentrating mechanism Am J Physiol Renal Physiol, February 1, 1998; 274(2): F413 - F424. [Abstract] [Full Text] [PDF]

				F. Park, D. L. Mattson, L. A. Roberts, and A. W. Cowley Jr. Evidence for the presence of smooth muscle alpha -actin within pericytes of the renal medulla Am J Physiol Regulatory Integrative Comp Physiol, November 1, 1997; 273(5): R1742 - R1748. [Abstract] [Full Text] [PDF]

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Structural organization of the renal medulla: comparative and functional aspects