Struvite

Struvite

Crystals of struvite from dog urine
General
Category Phosphate mineral
Formula
(repeating unit)
NH4MgPO4·6H2O
Strunz classification 08.CH.40
Identification
Color Colourless, white (dehydrated), yellow or brownish, light gray
Crystal habit Euhedral to platey
Crystal system Orthorhombic - Pyramidal
Twinning On {001}
Cleavage {100} perfect
Fracture Uneven
Mohs scale hardness 1.5–2
Luster Vitreous to dull
Streak White
Diaphaneity Transparent to translucent
Specific gravity 1.7
Optical properties Biaxial (+) 2V Measured: 37°
Refractive index nα = 1.495 nβ = 1.496 nγ = 1.504
Birefringence δ = 0.009
Solubility Slightly soluble, dehydrates in dry, warm air
Other characteristics Pyroelectric and piezoelectric
References [1][2][3]

Struvite (magnesium ammonium phosphate) is a phosphate mineral with formula: NH4MgPO4·6H2O. Struvite crystallizes in the orthorhombic system as white to yellowish or brownish-white pyramidal crystals or in platey mica-like forms. It is a soft mineral with Mohs hardness of 1.5 to 2 and has a low specific gravity of 1.7. It is sparingly soluble in neutral and alkaline conditions, but readily soluble in acid.

Struvite urinary stones and crystals form readily in the urine of animals and humans that are infected with ammonia-producing organisms. They are potentiated by alkaline urine and high magnesium excretion (high magnesium/plant-based diets). They also are potentiated by a specific urinary protein, in domestic cats.

Name

Struvite was first described from medieval sewer systems in Hamburg Germany in 1845 and named for geographer and geologist Heinrich Christian Gottfried von Struve (772–1851).[2]

Occurrence

Struvite is occasionally found in canned seafood, where its appearance is that of small glass slivers, objectionable to consumers for aesthetic reasons but of no health consequence.[4]

Use of struvite as an agricultural fertilizer was in fact first described in 1857.

Struvite kidney stones

Struvite precipitates in alkaline urine, forming stones. Struvite is the most common mineral found in urinary tract stones in dogs,[5] and is found also in urinary tract stones of cats and humans. Struvite stones are potentiated by bacterial infection that hydrolyzes urea to ammonium and raises urine pH to neutral or alkaline values. Urea-splitting organisms include Proteus, Pseudomonas, Klebsiella, Staphylococcus, and Mycoplasma.

Even in the absence of infection, accumulation of struvite crystals in the urinary bladder is a problem frequently seen in housecats, with symptoms including difficulty urinating (which may be mistaken for constipation) or blood in the urine (hematuria). The protein cauxin, a protein excreted in large amounts in cat urine that acts to produce a feline pheromone, has recently been found to cause nucleation of struvite crystals in a model system containing the ions necessary to form struvite. This may explain some of the excess struvite production in domestic cats.[6] In the past, surgery has been required to remove struvite uroliths in cats; today, special acidifying low magnesium diets may be used to dissolve sterile struvite stones.

Upper urinary tract stones that involve the renal pelvis and extend into at least 2 calyces are classified as staghorn calculi. Although all types of urinary stones can potentially form staghorn calculi, approximately 75% are composed of a struvite-carbonate-apatite matrix.

Struvite enteroliths

Struvite is a common mineral found in enteroliths (intestinal concretions) in horses.[7]

Wastewater treatment

Struvite can be a problem in sewage and waste water treatment, particularly after anaerobic digesters release ammonium and phosphate from waste material. Struvite can form a scale on lines and belts, in centrifuges and pumps, clog system pipes and other equipment including the anaerobic digester itself. Struvite, also referred to as MAP, forms when there is a mole to mole to mole ratio (1:1:1) of magnesium, ammonia and phosphate in the wastewater. The magnesium can be found in soil, seawater as well as drinking water. Ammonia is broken down from the urea in wastewater, and phosphate, which is found through food, soaps and detergents. These elements in place, struvite is more likely to form in a high pH environment, where there is higher conductivity, lower temperatures, and higher concentrations of magnesium, ammonia and phosphate. Recovery of phosphorus from wastestreams as struvite and recycling those nutrients into agriculture as fertilizer appears promising, particularly in agricultural manure and municipal waste water treatment plants.

Having struvite scale in a wastewater treatment system can lead to great inefficiency within the plant or operation due to clogging of the pipes, pumps and equipment. There have been a few options to solve this issue. Replacing the pipes, using a hydro-jetter or a mechanical grinder, but many lines can be underground and have to consider the great amount of downtime and labor. Chemical cleaning is now predominately used to clear systems of struvite. Chemical cleaning products have been developed to remove and prevent struvite with minimal downtime. [8] [9][10]

References

Wikimedia Commons has media related to Struvite.
  1. http://rruff.geo.arizona.edu/doclib/hom/struvite.pdf Handbook of mineralogy
  2. 2.0 2.1 http://webmineral.com/data/Struvite.shtml Webmineral
  3. http://www.mindat.org/min-3811.html Mindat
  4. Connie Thompson (2011-03-10). "Suspected "glass" in canned fish actually natural crystal". Komo News. Retrieved 2013-08-28.
  5. "Uroliths". Shiloh Shepherd Genetic Task Force. February 2014. Retrieved 2014-02-07.
  6. Matsumoto, K.; Funaba, M (February 2008). "Factors affecting struvite (MgNH4PO4·6H2O) crystallization in feline urine". Biochim Biophys Acta. 1780 issue=2 (2): 233–9. doi:10.1016/j.bbagen.2007.09.013. PMID 17976920.
  7. Blue MG, Wittkopp RW (July 1981). "Clinical and structural features of equine enteroliths". Journal of the American Veterinary Medical Association 179 (1): 79–82. PMID 7251465.
  8. Robert T. Burns, Lara B. Moody, Forbes R. Walker, D. Raj Raman. "Laboratory and In-Situ Reductions of Soluble Phosphorus in Liquid Swine Waste Slurries" (PDF). Environmental Technology 22: 1273–1278. doi:10.1080/09593332208618190. Retrieved 2011-07-16.
  9. Mark Hume. "Sewage plant carries sweet smell of phosphorus". The Globe And Mail. Retrieved 2014-07-08.
  10. Brian Morton. "Reclaiming minerals from waste water to make fertilizer". The Vancouver Sun. Retrieved 2013-06-05.

External links