Urine-Concentrating Mechanism in the Inner Medulla

逆流交换 肾髓质 重吸收 髓质 生物物理学 渗透浓度 肾单位 管状流体 直肌血管 渗透 亨利环 尿渗透压 肾乳头 髓腔 渗透压 解剖 化学 内科学 医学 生物 生物化学
作者
William H. Dantzler,Anita T. Layton,Harold E. Layton,Thomas L. Pannabecker
出处
期刊:Clinical Journal of The American Society of Nephrology [Lippincott Williams & Wilkins]
卷期号:9 (10): 1781-1789 被引量:90
标识
DOI:10.2215/cjn.08750812
摘要

Summary The ability of mammals to produce urine hyperosmotic to plasma requires the generation of a gradient of increasing osmolality along the medulla from the corticomedullary junction to the papilla tip. Countercurrent multiplication apparently establishes this gradient in the outer medulla, where there is substantial transepithelial reabsorption of NaCl from the water-impermeable thick ascending limbs of the loops of Henle. However, this process does not establish the much steeper osmotic gradient in the inner medulla, where there are no thick ascending limbs of the loops of Henle and the water-impermeable ascending thin limbs lack active transepithelial transport of NaCl or any other solute. The mechanism generating the osmotic gradient in the inner medulla remains an unsolved mystery, although it is generally considered to involve countercurrent flows in the tubules and vessels. A possible role for the three-dimensional interactions between these inner medullary tubules and vessels in the concentrating process is suggested by creation of physiologic models that depict the three-dimensional relationships of tubules and vessels and their solute and water permeabilities in rat kidneys and by creation of mathematical models based on biologic phenomena. The current mathematical model, which incorporates experimentally determined or estimated solute and water flows through clearly defined tubular and interstitial compartments, predicts a urine osmolality in good agreement with that observed in moderately antidiuretic rats. The current model provides substantially better predictions than previous models; however, the current model still fails to predict urine osmolalities of maximally concentrating rats.
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