Kidney countercurrent multiplication

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Kidney countercurrent multiplication

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A group of researchers is studying differences between nephrons of the kangaroo rat and humans. They find that the kangaroo rat has a relatively long loop of Henle, allowing the osmolarity at the bend to reach over 3000 mOsm/L. They discover a process of using energy to generate an osmotic gradient that enables both rats and humans to reabsorb water from tubular fluid and produce concentrated urine. Which of the following terms best describes the process described in the stem above?  

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If we take a cross-section of the kidney, there are two main parts, the outer cortex and the inner medulla.

If we zoom in, there are millions of tiny functional units called nephrons which go from the outer cortex down into the medulla and back out into the cortex again.

These nephrons perform the major function of the kidney, which is to clear harmful substances from the body by filtering the blood.

Each nephron is made up of the glomerulus, or a tiny clump of capillaries, where blood filtration begins.

The stuff that gets filtered into the tubule is called the filtrate, and the rest of it leaves the glomerulus through the efferent arteriole.

Interestingly, the blood that leaves these glomeruli does not enter into venules. Instead the efferent arterioles divide into capillaries a second time. These peritubular capillaries then reunite and at that point the blood enters venules and eventually drains back into the venous system.

Now, The renal tubule is a structure with several segments: the proximal convoluted tubule, the U- shaped loop of Henle with a descending and ascending limb and the distal convoluted tubule, which winds and twists back up again, before emptying into the collecting duct, which collects the final urine.

Now, zooming in on this nephron’s tubule, each one’si lined by brush border cells which have two surfaces. One is the apical surface which faces the tubular lumen and is lined with microvilli, which are tiny little projections that increase the cell’s surface area to help with solute reabsorption.

The other is the basolateral surface, which faces the peritubular capillaries, which run alongside the nephron.

The urine osmolarity is the concentration of urine, and is measured in Osmoles per liter, which is the solute particles that exist in a liter of urine.

To concentrate urine, or increase its osmolarity, nephrons rely on the corticopapillary gradient, which is a concentration gradient that spans from the cortex to the papilla which is the innermost tip of the medulla. In other words there are a lot of solutes in the interstitium with more solutes down here then up here.

So as a tubule dives deeper down into the medulla, the surrounding interstitium gets more and more hypertonic relative to the lumen of the tubule, and that drives more and more water out of the tubule, the deeper it goes. So you can see how important the corticopapillary gradient is - it prevents us from unnecessarily losing water - like a water recycling mechanism.

Summary

Kidney countercurrent multiplication refers to the process in which energy is used to create an osmotic gradient that enables the reabsorption of water from the tubular fluid, so that urine can be concentrated. Countercurrent multiplication creates this gradient by actively moving sodium chloride from the tubular fluid into the interstitial space deep within the kidneys.

Sources

  1. "Medical Physiology" Elsevier (2016)
  2. "Physiology" Elsevier (2017)
  3. "Human Anatomy & Physiology" Pearson (2017)
  4. "Evidence That the Mammalian Nephron Functions as a Countercurrent Multiplier System" Science (1958)
  5. "Micropuncture study of the mammalian urinary concentrating mechanism: evidence for the countercurrent hypothesis" American Journal of Physiology-Legacy Content (1959)
  6. "Current multiplier for use with ultramicroelectrodes" Analytical Chemistry (1986)
  7. "Principles of Anatomy and Physiology" Wiley (2014)
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