Citations to this article
Abstract
The mean bone pyrophosphate was 0.360 +/- 0.15 mg/g in 8 controls and 1.22 +/- 1.39 mg/g bone in 27 uremic patients (P less than 0.0025). 13 of the 27 uremic patients had bone pyrophosphate levels greater than 2 SD above control values. The ash content of uremic bones with increased pyrophosphate levels (group II) was 56 +/- 9% as compared to 64 +/- 2% in control bones (P less than 0.01) and 60 +/- 7% in uremic bones having normal pyrophosphate levels (P less than 0.1) (group I). The magnesium content of bones in group II was 338 +/- 47 as compared to 211 +/- 13 (P less than 0.0005) in the controls and 294 +/- 73 mmol/kg ash (P less than 0.05) in group I. In group II, but not group I, there was a significant inverse correlation between duration of dialysis and percent bone ash (r = -0.59) (P less than 0.05). A definite relationship existed between elevated bone pyrophosphate levels and soft tissue calcification. In group II the mean pulmonary calcium content was 530 +/- 459 as compared to 32 +/- 26 mmol/kg/ash in group I (P less than 0.0025). All patients with a bone pyrophosphate level greater than 1.4 mg/g bone had extensive pulmonary calcification. It is concluded that the excess bone pyrophosphate present in some uremic patients is either deposited in the apatite crystal in the transphosphorylated form or else as the magnesium salt since the pyrophosphate is resistant to pyrophosphatase and surface adsorption of pyrophosphate is not altered by the increased bone pyrophosphate levels. The excess bone pyrophosphate could disturb bone calcification mechanisms in uremic patients. The association between increased bone pyrophosphate and soft tissue calcification suggests that the disordered pyrophosphate metabolism may be important in the pathogenesis of extraosseous calcification.
Authors
A C Alfrey, C C Solomons
Total citations by year
Citations to this article (23)
| Title and authors | Publication | Year |
|---|---|---|
|
Levels of Potentially Toxic and Essential Elements in Water and Estimation of Human Health Risks in a River Located at the Interface of Brazilian Savanna and Amazon Biomes (Tocantins River)
Acioly TM, da Silva MF, Barbosa LA, Iannacone J, Viana DC |
Toxics | 2024 |
|
A new enzymatic assay to quantify inorganic pyrophosphate in plasma.
Lundkvist S, Niaziorimi F, Szeri F, Caffet M, Terry SF, Johansson G, Jansen RS, van de Wetering K |
Analytical and Bioanalytical Chemistry | 2022 |
|
The membrane protein ANKH is crucial for bone mechanical performance by mediating cellular export of citrate and ATP
F Szeri, S Lundkvist, S Donnelly, UF Engelke, K Rhee, CJ Williams, JP Sundberg, RA Wevers, RE Tomlinson, RS Jansen, K van de Wetering, M Mycielska |
PLoS genetics | 2020 |
|
Aluminium toxicosis: a review of toxic actions and effects
IO Igbokwe, E Igwenagu, NA Igbokwe |
Interdisciplinary toxicology | 2019 |
|
FGF-23 and secondary hyperparathyroidism in chronic kidney disease
J Silver, T Naveh-Many |
Nature Reviews Nephrology | 2013 |
|
Nolph and Gokal’s Textbook of Peritoneal Dialysis
R Khanna, RT Krediet |
2009 | |
|
Calcification and cardiovascular problems in renal failure
M Ketteler, ML Gross, E Ritz |
Kidney International | 2005 |
|
When man turns to stone: Extraosseous calcification in uremic patients
J Floege |
Kidney International | 2004 |
|
Cardiovascular calcification in patients with end-stage renal disease: A century-old phenomenon
WY Qunibi, CA Nolan, JC Ayus |
Kidney International | 2002 |
|
Scintigraphy in the clinical evaluation of disorders of mineral and skeletal metabolism in renal failure
FA de Jonge, EK Pauwels, NA Hamdyl |
European Journal of Nuclear Medicine | 1991 |
|
Soft tissue calcification in pediatric patients with end-stage renal disease
DS Milliner, AR Zinsmeister, E Lieberman, B Landing |
Kidney International | 1990 |
|
Chronic Renal Failure
GR Catto |
1988 | |
|
Sodium Thiosulfate Treatment of Soft -Tissue Calcifications in Patients with End-Stage Renal Disease
H Yatzidis, B Agroyannis |
Peritoneal dialysis international : journal of the International Society for Peritoneal Dialysis | 1987 |
|
Myocardial and vascular uptake of a bone tracer associated with secondary hyperparathyroidism
T Kida, Y Hujita, M Sasaki, J Inoue |
European Journal of Nuclear Medicine | 1986 |
|
Diffuse pulmonary uptake of 99mTc bone-imaging agents: Case report and survey
JL Coolens, P Devos, MD Roo |
European Journal of Nuclear Medicine | 1985 |
|
Osteopathien
S Bosnjakovic-Büscher, L Diethelm, HH Ellegast, H Fritz, I Greinacher, F Heuck, O Mehls, HC Oppermann, K Reinhardt, HW Schneider, J Spranger |
1983 | |
|
Pathogenesis of chondrocalcinosis and pseudogout. Metabolism of inorganic pyrophosphate and production of calcium pyrophosphate dihydrate crystals
A Caswell, DF Guilland-Cumming, PR Hearn, MK McGuire, RG Russell |
Annals of the rheumatic diseases | 1983 |
|
Röntgendiagnostik der Skeleterkrankungen / Diseases of the Skeletal System (Roentgen Diagnosis)
S Bosnjakovic-Büscher, L Diethelm, HH Ellegast, H Fritz, I Greinacher, F Heuck, O Mehls, HC Oppermann, K Reinhardt, HW Schneider, J Spranger, L Diethelm, F Heuck |
1983 | |
|
Proceedings of a symposium on crystal-related arthropathies. 22 October and 23 October, 1982, Bristol Polytechnic, Bristol.
|
Annals of the rheumatic diseases | 1983 |
|
Inhibitors of calcium phosphate precipitation and their role in biological mineralization
H Fleisch |
Journal of Crystal Growth | 1981 |
|
Effect of EHDP on calcium accumulation and technetium-99m pyrophosphate uptake in experimental myocardial infarction
LM Buja, AJ Tofe, RW Parkey, MD Francis, SE Lewis, PV Kulkarni, FJ Bonte, JT Willerson |
Circulation | 1981 |
|
Pulmonary calcification in hemodialyzed patients detected by technetium-99m diphosphonate scanning
PF Faubert, WB Shapiro, JG Porush, SY Chou, JM Gross, E Bondi, G Gomez-Leon |
Kidney International | 1980 |
|
Replacement of Renal Function by Dialysis
W Drukker, FM Parsons, JF Maher |
1979 |
Copyright © 2025 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)