Renal medulla explained

Renal medulla
Latin:medulla renalis
System:Urinary system

The renal medulla (Latin: medulla renis 'marrow of the kidney') is the innermost part of the kidney. The renal medulla is split up into a number of sections, known as the renal pyramids. Blood enters into the kidney via the renal artery, which then splits up to form the segmental arteries which then branch to form interlobar arteries. The interlobar arteries each in turn branch into arcuate arteries, which in turn branch to form interlobular arteries, and these finally reach the glomeruli. At the glomerulus the blood reaches a highly disfavourable pressure gradient and a large exchange surface area, which forces the serum portion of the blood out of the vessel and into the renal tubules. Flow continues through the renal tubules, including the proximal tubule, the loop of Henle, through the distal tubule and finally leaves the kidney by means of the collecting duct, leading to the renal pelvis, the dilated portion of the ureter.

The renal medulla contains the structures of the nephrons responsible for maintaining the salt and water balance of the blood. These structures include the vasa rectae (both spuria and vera), the venulae rectae, the medullary capillary plexus, the loop of Henle, and the collecting tubule.[1] The renal medulla is hypertonic to the filtrate in the nephron and aids in the reabsorption of water.

Blood is filtered in the glomerulus by solute size. Ions such as sodium, chloride, potassium, and calcium are easily filtered, as is glucose. Proteins are not passed through the glomerular filter because of their large size, and do not appear in the filtrate or urine unless a disease process has affected the glomerular capsule or the proximal and distal convoluted tubules of the nephron.

Though the renal medulla only receives a small percentage of the renal blood flow, the oxygen extraction is very high, causing a low oxygen tension and more importantly, a critical sensitivity to hypotension, hypoxia, and blood flow.[2] The renal medulla extracts oxygen at a ratio of ~80% making it exquisitely sensitive to small changes in renal blood flow. The mechanisms of many perioperative renal insults are based on the disruption of adequate blood flow (and therefore oxygen delivery) to the renal medulla.

Interstitium

The medullary interstitium is the tissue surrounding the loop of Henle in the medulla. It functions in renal water reabsorption by building up a high hypertonicity, which draws water out of the thin descending limb of the loop of Henle and the collecting duct system. Hypertonicity, in turn, is created by an efflux of urea from the inner medullary collecting duct.[3]

Pyramids

Renal pyramids
Latin:pyramides renales
System:Urinary system

Renal pyramids (or malpighian pyramids or Malpighi's pyramids named after Marcello Malpighi, a seventeenth-century anatomist) are cone-shaped tissues of the kidney. In humans, the renal medulla is made up of 10 to 18 of these conical subdivisions.[4] The broad base of each pyramid faces the renal cortex, and its apex, or papilla, points internally towards the pelvis. The pyramids appear striped because they are formed by straight parallel segments of nephrons' Loops of Henle and collecting ducts. The base of each pyramid originates at the corticomedullary border and the apex terminates in a papilla, which lies within a minor calyx, made of parallel bundles of urine collecting tubules.

Papilla

The renal papilla is the location where the renal pyramids in the medulla empty urine into the minor calyx in the kidney. Histologically it is marked by medullary collecting ducts converging to form a papillary duct to channel the fluid. Transitional epithelium begins to be seen.

Clinical significance

Some chemicals toxic to the kidney, called nephrotoxins, damage the renal papillae. Damage to the renal papillae may result in death to cells in this region of the kidney, called renal papillary necrosis. The most common toxic causes of renal papillary necrosis are NSAIDs, such as ibuprofen, acetylsalicylic acid, and phenylbutazone, in combination with dehydration. Perturbed renal papillary development has also been shown to be associated with onset of functional obstruction and renal fibrosis.[5] [6] [7]

Renal papillary damage has also been associated with nephrolithiasis and can be quantified according to the papillary grading score, which accounts for contour, pitting, plugging and Randall's plaque.[8]

See also

External links

Notes and References

  1. Book: Kelly CR, Landman J . The Netter Collection of Medical Illustrations: Urinary System. . Elsevier Health Sciences . March 2012 . plate 337. 2nd. 5. 978-1437722383.
  2. Book: Pardo M . Miller's Basics of Anesthesia . 2022 . Elsevier . 978-0-323-79677-4 . 553–554 . 8th.
  3. Book: Boron WG . Medical Physiology: A Cellular And Molecular Approaoch . Elsevier/Saunders . 2003 . 1300 . 1-4160-2328-3 . Page 837
  4. Book: Young B, O'Dowd G, Woodford P . Wheater's Functional Histology. 2014. Elsevier. Philadelphia, PA. 978-0-7020-4747-3. 293. 6.
  5. Wilkinson L, Kurniawan ND, Phua YL, Nguyen MJ, Li J, Galloway GJ, Hashitani H, Lang RJ, Little MH . 6 . Association between congenital defects in papillary outgrowth and functional obstruction in Crim1 mutant mice . The Journal of Pathology . 227 . 4 . 499–510 . August 2012 . 22488641 . 10.1002/path.4036 . 2777257 .
  6. Phua YL, Gilbert T, Combes A, Wilkinson L, Little MH . Neonatal vascularization and oxygen tension regulate appropriate perinatal renal medulla/papilla maturation . The Journal of Pathology . 238 . 5 . 665–676 . April 2016 . 26800422 . 10.1002/path.4690 . 11343/291071 . 13482413 . free .
  7. Phua YL, Martel N, Pennisi DJ, Little MH, Wilkinson L . Distinct sites of renal fibrosis in Crim1 mutant mice arise from multiple cellular origins . The Journal of Pathology . 229 . 5 . 685–696 . April 2013 . 23224993 . 10.1002/path.4155 . 22837861 .
  8. Cohen AJ, Borofsky MS, Anderson BB, Dauw CA, Gillen DL, Gerber GS, Worcester EM, Coe FL, Lingeman JE . 6 . Endoscopic Evidence That Randall's Plaque is Associated with Surface Erosion of the Renal Papilla . Journal of Endourology . 31 . 1 . 85–90 . January 2017 . 27824271 . 5220550 . 10.1089/end.2016.0537 .