An assessment of cinacalcet HCl effects on bone histology in dialysis patients with secondary hyperparathyroidism.

AIMS: Cinacalcet lowers plasma parathyroid hormone (PTH) levels in patients with secondary hyperparathyroidism (sHPT), but the bone histologic response has not been described. This prospective, double-blind, placebo-controlled trial assessed the effects of cinacalcet on bone histology and serum markers of bone metabolism in dialysis patients with sHPT. METHODS: Patients with intact PTH (iPTH) > or = 300 pg/ml were randomly assigned 2:1 to receive cinacalcet or placebo with concurrent vitamin D and/or phosphate binder therapy. Cinacalcet (30 - 180 mg/day) was used to achieve iPTH levels < or = 200 pg/ml. Bone biopsies were performed before and after one year of treatment. RESULTS: Baseline and end-of-study data were available from 32 patients (19 cinacalcet, 13 placebo). Baseline bone turnover was elevated in 27, reduced in 3 and normal in 2 patients. Serum bone-specific alkaline phosphatase (BSAP) and N-telopeptide (NTx) were elevated. Cinacalcet treatment decreased PTH and diminished activation frequency, bone formation rate/bone surface, and fibrosis surface/bone surface. Adynamic bone was observed in three patients receiving cinacalcet; in two of these, PTH levels were persistently low (< 100 pg/ml). The histomorphometric parameter changes in bone corresponded to PTH, BSAP and NTx reductions. Bone mineralization parameters remained normal. CONCLUSIONS: Treatment with cinacalcet lowered PTH and reduced bone turnover and tissue fibrosis among most dialysis patients with biochemical evidence of sHPT.

A characterization of vitamin D-independent intestinal calcium absorption in the osteopetrotic (op/op) mouse.

Previous work in our laboratory showed that the osteopetrotic (op/op) mouse possesses a vitamin D-independent mechanism of intestinal calcium absorption. This study was performed in an effort to further characterize the mechanism. The vitamin D-deficient op/op mouse absorbed calcium faster than either a vitamin D-deficient or 1, 25-dihydroxyvitamin D(3)-supplemented wild-type mouse. This increased rate of absorption was not found at concentrations of calcium that result in diffusional calcium absorption. Thus, vitamin D-deficient op/op mice had intestinal calcium absorption similar to that of vitamin D-deficient wild-type littermates when increasing levels of calcium were administered. Also, mRNA and protein levels of calbindin-D9k were similar in vitamin D-deficient wild-type and op/op mice as well as in wild-type and op/op mice treated with 1, 25-dihydroxyvitamin D(3). Therefore, the mechanism of vitamin D-independent intestinal calcium absorption in the op/op mouse is distinct from vitamin D-dependent intestinal calcium absorption.

Hypophosphatemia and the development of rickets in osteopetrotic (op/op) mice.

Our previous work has shown that op/op mice hyperabsorb dietary calcium in the vitamin D-deficient state and shunt that calcium into bone. Under these conditions, the op/op mice are hypocalcemic. The purpose of this study was to examine calcium metabolism and bone mineralization in vitamin D-deficient op/op mice. First, the op/op mice and their normal littermates were placed on a vitamin D-deficient, low phosphorus diet to limit bone mineralization. Under these circumstances, op/op mice survived, even when calcium was also removed from the diet. If the diet contained phosphate, op/op mice died from hypocalcemic tetany when calcium was also removed from the diet. Furthermore, serum calcium levels became similar to wild type in the op/op mice administered the vitamin D-deficient, low phosphorus diet, and op/op mice were able to increase serum calcium in response to 1,25-dihydroxyvitamin D3. The op/op mice developed rickets when their serum phosphorus level was too low to support bone mineralization. The op/op mice became hypophosphatemic on regimens in which normal mice were able to maintain normal serum phosphorus levels. It appears that the op/op mouse simply requires a higher dietary calcium and phosphorus level to prevent rickets and hypocalcemic tetany since the bone is not available as a source of these minerals. However, the ability of the op/op mouse to mineralize bone at low serum calcium and phosphorus levels remains unexplained.

Osteopetrotic (op/op) mice are unable to maintain serum calcium levels despite hyperabsorption of calcium.

The effect of vitamin D on serum calcium, vitamin D receptor (VDR) protein level, and fate of radioactive calcium ingested were compared in vitamin D-deficient osteopetrotic (op/op) mice and their wild-type vitamin D-deficient littermates. Vitamin D deficiency was achieved in mice after feeding them a vitamin D-deficient diet for 5-6 weeks. Serum calcium did not increase in op/op mice in response to 1,25-dihydroxyvitamin D3. Furthermore, op/op mice were not capable of increasing serum calcium levels by passively absorbing calcium from the diet. These defects in calcium homeostasis were neither the result of the inability of the VDR to bind its ligand, as determined by the hydroxylapatite assay, nor the result of abnormal regulation of intestinal VDR, as determined by the enzyme-linked immunosorbent assay. Upon administration of radioactive calcium by oral gavage, it was found that vitamin D-deficient, op/op mice had an extremely efficient mechanism to absorb dietary calcium, but the calcium absorbed was readily shunted into bone; thus serum calcium did not increase. In addition, op/op mice also possessed vitamin D-stimulated intestinal calcium absorption, but this process was muted by the overwhelming vitamin D-independent mechanism of dietary calcium absorption.