High-dose oral pyrophosphate inhibits connective tissue calcification in Abcc6 null mice but affects bone structure.

is a rare inherited disorder marked by abnormal calcium phosphate deposition in soft connective tissues, particularly the skin, arteries, and eyes. It is caused by inactivating mutations in the gene, which encodes a hepatic efflux transporter. Loss of ABCC6 function leads to reduced plasma levels of pyrophosphate, a key inhibitor of calcification, thereby promoting ectopic mineralization. Oral pyrophosphate therapy has emerged as a potential treatment, but its effectiveness is uncertain. Most ingested pyrophosphate is hydrolyzed in the gut to inorganic phosphate, which may worsen calcification. Moreover, its impact on mineralized tissues remains largely unexplored. mice closely mimic human pseudoxanthoma elasticum and are widely used in preclinical studies. Although patients are most concerned about ocular complications, eye calcification is rarely assessed in translational studies using Abcc6-/- mice. Using microcomputed tomography we found that ectopic calcification at the ciliary margin is a reliable marker of ocular disease progression in these mice. Administering pyrophosphate in drinking water at concentrations up to 90 mM did not increase calcification in skin or eyes. However, only very high doses effectively prevented ectopic calcification - doses that would equate to an impractical 2.5 g/kg/day of disodium pyrophosphate in humans. These high doses also led to pyrophosphate accumulation in bone and negatively affected bone structure and strength. , only supraphysiological doses of orally administered pyrophosphate inhibited ectopic calcification in mice, but these doses are not feasible for human use and may compromise bone function. These data are especially important considering the currently ongoing clinical trial evaluating the safety and efficacy of oral pyrophosphate administration as a treatment for pseudoxanthoma elasticum.