Relative effectiveness of vitamin D metabolites in increasing bone mineral solubility

Abstract

Weanling rats were given a vitamin D-deficient diet containing 1.4% calcium and 1.0% phosphorus. After 4 weeks these deficient animals were injected for 7 days with selected doses of one of the following vitamin D metabolites: 25(OH)D₃, 1,25(OH)₂D₃, 24,25(OH)₂D₃, 25,26(OH)₂D₃ or the ethanol vehicle. A vitamin D-replete group was placed on the same diet but injected with 50 IU of vitamin D₃ once a week for the entire 5-week period. By the use of a modified Ussing chamber [1], the measurements of calcium fluxes into and from the rat calvaria were possible. These data enabled the apparent mineral solubilities to be derived. After 5 weeks on this diet the vitamin D-deficient rats had low levels of serum calcium (1.41 mM) and decreased mineral solubility when compared to the vitamin D-replete group. The apparent solubility of the bone mineral increased toward the vitamin D-replete level in calvaria from vitamin D metabolite-treated rats. However, these changes did not directly reflect the alterations in the level of serum calcium. At any given dose level, 1,25(OH)₂D₃ was the most effective metabolite in increasing serum calcium. In fact, the high dose (250 pmoles/day) was hypercalcemic. Next in effectiveness was 25(OH)D₃. These two metabolites were equally effective in increasing mineral solubility. At a 10 times higher dose, the 24,25(OH)₂D₃ metabolite was able to normalize serum calcium and improve but not normalize mineral solubility. At the high dose (260 pmoles/day), the 25,26(OH)₂D₃ metabolite caused no effect on mineral solubility and minimal increases in serum calcium.