Renal tubular acidosis

Renal tubular acidosis

Significant bilateral nephrocalcinosis (calcification of the kidneys) on a frontal X-ray (radiopacities (white) in the right upper and left upper quadrant of the image), as seen in distal renal tubular acidosis.
Classification and external resources
Specialty urology
ICD-10 N25.8
ICD-9-CM 588.89
OMIM 179800
DiseasesDB

11687 11673

11705
eMedicine med/1071
MeSH D000141

Renal tubular acidosis (RTA) is a medical condition that involves an accumulation of acid in the body due to a failure of the kidneys to appropriately acidify the urine.[1] When blood is filtered by the kidney, the filtrate passes through the tubules of the nephron, allowing for exchange of salts, acid equivalents, and other solutes before it drains into the bladder as urine. The metabolic acidosis that results from RTA may be caused either by failure to recover sufficient (alkaline) bicarbonate ions from the filtrate in the early portion of the nephron (proximal tubule) or by insufficient secretion of (acid) hydrogen ions into the latter portions of the nephron (distal tubule). Although a metabolic acidosis also occurs in those with renal insufficiency, the term RTA is reserved for individuals with poor urinary acidification in otherwise well-functioning kidneys. Several different types of RTA exist, which all have different syndromes and different causes.

The word acidosis refers to the tendency for RTA to lower the blood's pH. When the blood pH is below normal (7.35), this is called acidemia. The metabolic acidosis caused by RTA is a normal anion gap acidosis.

Types

An overview of types 1, 2, and 4 is presented below (type 3 is usually excluded from modern classifications):

Type Type 1 Type 2 Type 4
Location Collecting Tubules Proximal tubules Adrenal
Acidemia Yes (severe) Yes Mild when present
Potassium Hypokalemia Hypokalemia Hyperkalemia
Pathophysiology Failure of H+ secretion by the α intercalated cells and reclaim K Failed HCO3 reabsorption from the urine by the proximal tubular cells Deficiency of aldosterone, or a resistance to its effects, (hypoaldosteronism or pseudohypoaldosteronism)

Type 1-Distal RTA

Radiograph of a child with rickets, a complication of both distal and proximal RTA.

Distal RTA (dRTA) is the classical form of RTA, being the first described. Distal RTA is characterized by a failure of H+ secretion into lumen of nephron by the alpha intercalated cells of the medullary collecting duct of the distal nephron. This failure of acid secretion may be due to a number of causes, and it leads to an inability to acidify the urine to a pH of less than 5.3. Because renal excretion is the primary means of eliminating H+ from the body, there is consequently a tendency towards acidemia. There is an inability to excrete H+
while K+
cannot be reclaimed by the cell, leading to acidemia (as H+
builds up in the body) and hypokalemia (as K+
cannot be reabsorbed by the alpha cell). This leads to the clinical features of dRTA;[1] In other words, the intercalated cells' apical H+/K+ antiporter is non-functional, resulting in proton retention and potassium excretion. Since calcium phosphate stones demonstrate a proclivity for deposition at higher pHs (alkaline), the substance of the kidney develops stones bilaterally; this does not occur in the other RTA types.

Type 2-Proximal RTA

Proximal RTA (pRTA) is caused by a failure of the proximal tubular cells to reabsorb filtered bicarbonate from the urine, leading to urinary bicarbonate wasting and subsequent acidemia. The distal intercalated cells function normally, so the acidemia is less severe than dRTA and the urine can acidify to a pH of less than 5.3.[3] pRTA also has several causes, and may occasionally be present as a solitary defect, but is usually associated with a more generalized dysfunction of the proximal tubular cells called Fanconi syndrome, in which there is also phosphaturia, glycosuria, aminoaciduria, uricosuria, and tubular proteinuria.

The principal feature of Fanconi syndrome is bone demineralization (osteomalacia or rickets) due to phosphate wasting.

Type 3 RTA-Combined proximal and distal RTA

In some patients, RTA shares features of both dRTA and pRTA. This rare pattern was observed in the 1960s and 1970s as a transient phenomenon in infants and children with dRTA (possibly in relation with some exogenous factor such as high salt intake) and is no longer observed.[4] This form of RTA has also been referred to as juvenile RTA.[5]

Combined dRTA and pRTA is also observed as the result of inherited carbonic anhydrase II deficiency. Mutations in the gene encoding this enzyme give rise to an autosomal recessive syndrome of osteopetrosis, renal tubular acidosis, cerebral calcification, and mental retardation.[6][7][8] It is very rare and cases from all over the world have been reported, of which about 70% are from the Magreb region of North Africa, possibly due to the high prevalence of consanguinity there.[9] The kidney problems are treated as described above. There is no treatment for the osteopetrosis or cerebral calcification.

Type 3 is rarely discussed.[10] Most comparisons of RTA are limited to a comparison of types 1, 2, and 4.

Type 4 RTA

Type 4 RTA is due either to a deficiency of Aldosterone, or to a resistance to its effects.

Type 4 RTA is not actually a tubular disorder at all nor does it have a clinical syndrome similar to the other types of RTA described above. It was included in the classification of renal tubular acidoses as it is associated with a mild (normal anion gap) metabolic acidosis due to a physiological reduction in proximal tubular ammonium excretion (impaired ammoniagenesis), which is secondary to hypoaldosteronism, and results in a decrease in urine buffering capacity. Its cardinal feature is hyperkalemia, and measured urinary acidification is normal, hence it is often called hyperkalemic RTA or tubular hyperkalemia.[10]

Causes include:

  1. Drugs: NSAIDs, ACE inhibitors and ARBs, Eplerenone, Spironolactone, Trimethoprim, Pentamidine
  2. Pseudohypoaldosteronism

History

Renal tubular acidosis was first described in 1935 by Lightwood and 1936 by Butler et al. in children.[11][12] Baines et al. first described it in adults in 1945.[13]

Lewis postulated the Dickens character, Tiny Tim in A Christmas Carol, was suffering from renal tubular acidosis.[14]

Researchers published PLOS ONE in 2009 speculated that the infamously afflicted Charles II of Spain may have suffered from renal tubular acidosis in tandem with combined pituitary hormone deficiency.[15]

See also

References

  1. 1 2 Laing CM, Toye AM, Capasso G, Unwin RJ (2005). "Renal tubular acidosis: developments in our understanding of the molecular basis". Int. J. Biochem. Cell Biol. 37 (6): 1151–61. doi:10.1016/j.biocel.2005.01.002. PMID 15778079.
  2. Buckalew VM Jr (1989). "Nephrolithiasis in renal tubular acidosis". The Journal of Urology 141 (3 (part 2)): 731–737. PMID 2645431.
  3. Rodriguez Soriano J, Boichis H, Stark H, Edelmann CM (1967). "Proximal renal tubular acidosis. A defect in bicarbonate reabsorption with normal urinary acidification". Pediatr. Res. 1 (2): 81–98. doi:10.1203/00006450-196703000-00001. PMID 6029811.
  4. Rodríguez Soriano J (August 2002). "Renal tubular acidosis: the clinical entity". J. Am. Soc. Nephrol. 13 (8): 2160–70. doi:10.1097/01.ASN.0000023430.92674.E5. PMID 12138150.
  5. de Jong PE, Koomans HA, Weening JJ (2000). Klinische Nefrologie (3rd ed.). Maarssen: Elsevier. pp. 141–2.
  6. Sly WS, Whyte MP, Sundaram V, et al. (July 1985). "Carbonic anhydrase II deficiency in 12 families with the autosomal recessive syndrome of osteopetrosis with renal tubular acidosis and cerebral calcification". N. Engl. J. Med. 313 (3): 139–45. doi:10.1056/NEJM198507183130302. PMID 3925334.
  7. Shah GN, Bonapace G, Hu PY, Strisciuglio P, Sly WS (September 2004). "Carbonic anhydrase II deficiency syndrome (osteopetrosis with renal tubular acidosis and brain calcification): novel mutations in CA2 identified by direct sequencing expand the opportunity for genotype-phenotype correlation". Hum. Mutat. 24 (3): 272. doi:10.1002/humu.9266. PMID 15300855.
  8. Pushkin A, Abuladze N, Gross E, et al. (August 2004). "Molecular mechanism of kNBC1-carbonic anhydrase II interaction in proximal tubule cells". J. Physiol. (Lond.) 559 (Pt 1): 55–65. doi:10.1113/jphysiol.2004.065110. PMC 1665076. PMID 15218065.
  9. Fathallah DM, Bejaoui M, Lepaslier D, Chater K, Sly WS, Dellagi K (1997). "Carbonic anhydrase II (CA II) deficiency in Maghrebian patients: evidence for founder effect and genomic recombination at the CA II locus" (PDF). Hum. Genet. 99 (5): 634–7. doi:10.1007/s004390050419. PMID 9150731.
  10. 1 2 Hyporeninemic Hypoaldosteronism at eMedicine
  11. Lightwood R. (1935). "Communication no. 1". Arch Dis Child 10: 205–6. doi:10.1136/adc.10.57.205.
  12. Butler AM, Wilson JL, Farber S (1936). "Dehydration and acidosis with calcification at renal tubules". The Journal of Pediatrics 8: 489–99. doi:10.1016/s0022-3476(36)80111-5.
  13. Baines AM, Barelay JA, Cooke WT (1945). "Nephrocalcinosis associated with hyperchloremia and low plasma-bicarbonate". Q J Med 14: 113–23.
  14. Lewis, Donald W. (1992). "What Was Wrong with Tiny Tim?". Archives of Pediatrics & Adolescent Medicine 146 (12): 1403–7. doi:10.1001/archpedi.1992.02160240013002. PMID 1340779.
  15. Alvarez, Gonzalo; Ceballos, Francisco C.; Quinteiro, Celsa; Bauchet, Marc (15 April 2009). "The Role of Inbreeding in the Extinction of a European Royal Dynasty". PLoS ONE 4 (4): e5174. doi:10.1371/journal.pone.0005174. PMC 2664480. PMID 19367331.
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