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Ultrafiltration (kidney)

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Filtration by a semi-permeable membrane
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Diagram showing the basic physiologic mechanisms of the kidney

In renal physiology, ultrafiltration occurs at the barrier between the blood and the filtrate in the glomerular capsule (Bowman's capsule) in the kidneys. As in nonbiological examples of ultrafiltration, pressure (in this case blood pressure) and concentration gradients lead to a separation through a semipermeable membrane (provided by the podocytes). The Bowman's capsule contains a dense capillary network called the glomerulus. Blood flows into these capillaries through the afferent arterioles and leaves through the efferent arterioles.

The high hydrostatic pressure forces small molecules in the tubular fluid such as water, glucose, amino acids, sodium chloride and urea through the filter, from the blood in the glomerular capsule across the basement membrane of the Bowman's capsule and into the renal tubules. This process is called ultrafiltration; the resulting fluid, virtually free of large proteins and blood cells, is referred to as glomerular filtrate, or ultrafiltrate. Further modification of ultrafiltrate, by reabsorption and secretion, transforms it into urine.

Glomerular pressure is about 75 millimeters of mercury (10 kPa). It is opposed by osmotic pressure (30 mmHg, 4.0 kPa) and hydrostatic pressure (20 mmHg, 2.7 kPa) of solutes present in capsular space. This difference in pressure is called effective pressure (25 mmHg, 3.3 kPa).

In hemodialysis centers, ultrafiltration takes place in a hemofilter on the hemodialysis machines, when the blood pressure is greater than the dialysate pressure (difference = transmembrane pressure (TMP)). This removes fluid from the blood while keeping its blood cells intact.

Selectivity

See also: Table of permselectivity for different substances

The structures of the layers of the glomerulus determine their permeability-selectivity (permselectivity). For instance, small ions such as sodium and potassium pass freely, while larger plasma proteins, such as hemoglobin tetramers, haptoglobin bound hemoglobin and albumin have practically no permeability at all. Also, negatively charged molecules will pass through far less frequently than positively charged ones.

Slow continuous ultrafiltration

Slow continuous ultrafiltration (SCUF) is an artificial method which approximately mimics the ultrafiltration function of the kidneys. SCUF is a continuous renal replacement therapy (CRRT) generally used to remove fluid from fluid overloaded patients with acute kidney failure. During SCUF blood is continuously removed from the body, passed through an extracorporeal circuit through a hemofilter, and send back to the body. A predetermined percentage of plasma water is removed in the hemofilter based upon a prescription. Typically, no more than 2 liters an hour of fluid is removed. Unlike hemodialysis, hemofiltration and hemodiafiltration, no dialysate or replacement fluids are used in SCUF.

See also

References

  1. Koushanpour, Esmail (1986). Renal Physiology. New York: Springer-Verlag. pp. 53–72. ISBN 978-0-387-96304-4.
  2. Ronco C, Bellomo R, Ricci Z (2001). "Hemodynamic response to fluid withdrawal in overhydrated patients treated with intermittent ultrafiltration and slow continuous ultrafiltration: role of blood volume monitoring". Cardiology. 96 (3–4): 196–201. doi:10.1159/000047404. PMID 11805387.
Physiology of the kidneys and acid–base physiology
Creating urine
Secretion
Reabsorption
Filtration
Other functions
Hormones
Fluid balanceBody water: Intracellular fluid/Cytosol
Acid–base balance
  • Darrow Yannet diagram
  • Base excess
  • Davenport diagram
  • Anion gap (Delta ratio)
  • Winters's formula
  • Buffering
  • Assessment and measurement
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