AI Article Synopsis
- Kidney stone disease (nephrolithiasis) is influenced by factors like dehydration and metabolic issues, with Randall's plaque being a key mineral deposit involved in stone formation.
- Recent research indicates that Randall's plaque is primarily composed of calcium phosphate (carbapatite) and serves as a nucleus for kidney stones, but how it forms is still not fully understood.
- An analysis of Randall's plaques revealed significantly higher zinc levels in carbapatite compared to regular kidney stones, suggesting that zinc might play a role in the underlying tissue reaction leading to plaque formation, warranting further study on its potential involvement in inflammation.
Article Abstract
Kidney stone disease, or nephrolithiasis, is a common ailment. Among the different risk factors usually associated with nephrolithiasis are dehydration, metabolic defects (especially with regard to calcium and oxalate). The presence of a mineral deposit at the surface of the renal papilla (termed Randall's plaque) has all been recently underlined. Of note, Randall's plaque is made of the calcium phosphate, carbapatite, and serves as a nucleus for kidney stone formation. The process by which apatite nanocrystals nucleate and form Randall's plaque remains unclear. This paper deals with the possible relationship between trace elements and the formation of this mineral. The investigation has been performed on a set of Randall's plaques, extracted from human kidney stones, through μ-X-ray diffraction and μ-X-ray fluorescence analyses in order to determine the chemical composition of the plaque as well as the nature and the amount of trace elements. Our data provide evidence that Zn levels are dramatically increased in carbapatite of RP by comparison to carbapatite in kidney stones, suggesting that calcified deposits within the medullar interstitium are a pathological process involving a tissue reaction. Further studies, perhaps including the investigation of biomarkers for inflammation, are necessary for clarifying the role of Zn in Randall's plaque formation.
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| http://dx.doi.org/10.1016/j.jtemb.2011.05.004 | DOI Listing |
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