Nephron Microscopic Anatomy

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The Renal Corpuscle

Glomerulus

Histology section of a normal renal corpuscle (© RVC 2008)
Histology section of a normal renal corpuscle (© RVC 2008)
Histology section of a normal renal corpuscle showing the layers of the bowmans capsule (© RVC 2008)
Histology section of renal tubules (© RVC 2008)
Histology section of the collecting duct showing the close proximity of the loop of henle (© RVC 2008)
Histology section of the collecting duct (© RVC 2008)
  • Made up of many parallel capillaries
  • These capillaries do not connect to venules as with other capillaries
  • Blood flows into these capillaries through a wide afferent arteriole and leaves through a narrower efferent arteriole
  • The flow from the efferant arteriole enters the peritubular capillaries surrounding the proximal tubule
  • This change in diameter maintains a high filtration pressure which is essential for filtration
  • Also the blood entering the afferent arteriole is at very high pressure already as it from the renal artery
  • The pressure actually forces molecules through the glomerular filtration barrier which is responsible for selectively filtering the blood forming the glomerular filtrate.
  • As well as the the cells in the blood vessels the other component of the glomerulus are the mesangial cells:
    • These give support to the glomerulus
    • Maintain glomerular basal lamina

The Bowmans Capsule

  • Surrounds the capillaries of the glomerulus
  • Has two layers separated by the urinary space
    • Inner visceral layer - Podocytes
    • Outer parietal layer
  • It is here where the filtrate is collected before entering the proximal tubule

The Physiology of the Renal Corpuscle

Details of the physiology of the renal corpuscle can be found here

Proximal Tubule

  • This is the piece of nephron which starts at the Bowmans capsule and ends in the loop of henle
  • Consists of two parts which differ in cell morphology and function
    • Pars convoluter - joins the urinary pole of the Bowmans capsule
    • Pars recta (straight part) - links the pars convoluter to the descending thin limb of the loop of henle
  • Has a brush border of densely packed microvilli to increase surface area
  • The basal lamina is striated to increase the surface area for reabsorption
    • Typical of actively ion transporting epithelial cells
    • Lots of mitochondria to provide energy for exchange
    • Lots of Na+ / K+ ATPases to maintain ion levels in cells at right level to allow efficient take up of ions from lumen

The Physiology of the Proximal Tubule

Details of the physiology of the proximal tubule can be found here

The Loop of Henle

The loop of henle basically consists of two parallel limbs which descend from the cortex into the medulla. They are joined at the bottom and as such the flow moves down one limb and up the other in opposite directions. This sets up a counter current exchange and allows the loop of henle to be the major site of water reabsorption along the nephron. It has three parts; the thin decsending limb, the thin ascending limb and the thick ascending limb

The Physiology of the Loop of Henle

Details of the physiology of the loop of henle can be found here

The Distal Tubule

  • Consists of two parts
    • Straight part - connects the thick ascending limb of the loop of henle to the convoluted distal tubule
    • Convoluted part - connects the straight part to the connecting duct
  • No brush border - very few micro villi (compared to the proximal tubule)
  • The basal lamina is striated to increase the surface area for reabsorption

The Physiology of the Distal Tubule

Details of the physiology of the distal tubule can be found here

Collecting Duct

  • This structure links the distal tubule to the area cribosa of the papilla into the renal pelvis
  • Here the final concentration of the urine occurs as the collecting duct makes the transition from the isotonic cortex to the hypertonic medulla the increasing osmolarity of the interstial fluid causes more and more water to be reabsorbed.
  • The collecting duct has 2 cell types
    • Intercalated cells
    • Principal cells
  • The cells are flat to cylindrical
  • Have clearly visible cell borders

The Physiology of the Collecting Duct

Details of the physiology of the collecting duct can be found here

Blood Supply to the Nephron

The blood enters the glomerulus through the afferent arteriole. It is filtered by the glomerulus and what remains in the blood vessels leaves this structure via the efferent arteriole. The vessel then winds around the proximal tubule and is thus called a peritubular capillary. As it works its way along the tubule it collects the reabsorbed substances which it originally lost in the glomerulus. As the tubule descends into the medulla and becomes the Loop of Henle the blood vessel follows it and becomes what is known as the vasa recta. Upon its exit from the the medulla it wraps itself around the distal tubule.

The Vasa Recta

Vasa Recta is the name given to blood vessels supplying the medullary region of the kidney. They are arranged in a U configuration but flow is opposite to that of the Loop of Henle. The blood vessels descend from the cortex down into the medulla. It supplies the nutrients and oxygen the Loop of Henle needs.

The physiology of the vasa recta can be found here

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