Ibandronate is a potent nitrogen-containing bisphosphonate. It has a strong affinity for bone mineral and potently inhibits osteoclast-mediated bone resorption. Ibandronate is effective for the treatment of hypercalcemia of malignancy, metastatic bone disease, postmenopausal osteoporosis, corticosteroid-induced osteoporosis, and Paget's disease. Oral ibandronate is rapidly absorbed (t(max) < 1 hour), with a low bioavailability (0.63%) that is further reduced (by up to 90%) in the presence of food. Ibandronate has a wide therapeutic index and is not metabolized and, therefore, has a low potential for drug interactions. Given its metabolic stability, ibandronate is eliminated from the blood by partitioning into bone (40%-50%) and through renal clearance (CL(R) approximately 60 mL/min). The CL(R) of ibandronate is linearly related to creatinine clearance. The sequestration of ibandronate in bone (V(D) > 90 L) results in a multiphasic elimination (t((1/2)) range approximately 10-60 hours), characterized by the slow release of ibandronate from the bone compartment. The potency of ibandronate and its sequestration into bone allow ibandronate to be developed as oral and intravenous injection formulations that can be administered with convenient extended between-dose intervals.
Multiple steps are involved in the metastasis of cancer cells from primary sites to distant organs. These steps should be considered in the design of pharmacologic approaches to prevent or inhibit the metastatic process. In the present study, we have compared the effects of inhibiting several steps involved in the bone metastatic process individually with inhibition of both together. The steps we chose were matrix metalloproteinase (MMP) secretion, likely involved in tumor cell invasion, and osteoclastic bone resorption, the final step in the process. We used an experimental model in which inoculation of human estrogen-independent breast cancer MDA-231 cells into the left cardiac ventricle of female nude mice causes osteolytic lesions in bone. To inhibit cancer invasiveness, the tissue inhibitor of the MMP-2 (TIMP-2), which is a natural inhibitor of MMPs, was over-
Ibandronate preserves the trabecular structure of the osseous epiphysis and prevents femoral head deformity during the early phase of repair of ischemic necrosis in the piglet model.
Ibandronate is a highly potent, nitrogen-containing bisphosphonate. Unlike most other bisphosphonates, it is under clinical development for both oral and intravenous (i.v.) administration. Ibandronate can be used in convenient intermittent regimens that may optimize therapeutic outcome with enhanced compliance by patients. The preclinical pharmacokinetics (PK) and pharmacology of ibandronate have been extensively explored in a large preclinical development program involving various recommended animal models of human osteoporosis. These experimental studies of ibandronate indicate that the preclinical pharmacology and PK profile of ibandronate are broadly similar to those of other nitrogen-containing bisphosphonates. The efficacy of intermittent administration of subcutaneous (s.c.) and i.v. ibandronate has been demonstrated in four animal models (rat, dog, minipig, and monkey). Thus in rats, dogs, and monkeys with estrogen depletion, and in minipigs with glucocorticoid-induced bone loss, ibandronate administered s.c. or i.v. with extended intervals between doses reduces bone turnover, increases bone mineral density, and maintains bone quality in a dose-dependent manner. Furthermore, studies in rats and dogs comparing continuous and intermittent treatment schedules indicate similar efficacy when the same cumulative dose is applied over the duration of the study. These studies with ibandronate illustrate the concept that the total cumulative dose of bisphosphonate administered determines the response, independent of whether the dose is given daily or less frequently in a given time period. The efficacy of intermittent regimens has also been verified in models of secondary osteoporosis due to secondary hyperparathyroidism or immobilization (both in rats), or due to glucocorticoids in minipigs. Important factors for determining efficacy and the magnitude of response are the doses given, the length of the interval between doses, and the underlying bone turnover rate. The mechanisms underlying the remarkable efficacy of intermittent bisphosphonate dosing are not fully understood and further research is needed. Importantly, ibandronate is the only bisphosphonate so far proven to reduce the risk of vertebral fractures significantly with a between-dose interval >2 months, in a prospective clinical trial. Collectively, the preclinical studies on ibandronate have provided a sound basis for the design of the convenient regimens currently being examined in clinical trials.
Bisphosphonates have emerged as a valuable treatment for postmenopausal osteoporosis. Bisphosphonate treatment is usually accompanied by a 3-6% gain in bone mineral density (BMD) during the first year of treatment and by a decrease in bone turnover. Despite low bone turnover, BMD continues to increase slowly beyond the first year of treatment. There is evidence that bisphosphonates not only increase bone volume but also enhance secondary mineralization. The present study was conducted to address this issue and to compare the effects of continuous and intermittent bisphosphonate therapy on static and dynamic parameters of bone structure, formation, and resorption and on mineral properties of bone. Sixty dogs were ovariohysterectomized (OHX) and 10 animals were sham-operated (Sham). Four months after surgery, OHX dogs were divided in six groups (n = 10 each). They received for 1 year ibandronate daily (5 out of 7 days) at a dose of 0, 0.8, 1.2, 4.1, and 14 µg/kg/day or intermittently (65 µg/kg/day, 2 weeks on, 11 weeks off). Sham dogs received vehicle daily. At month 4, there was a significant decrease in bone volume in OHX animals (p < 0.05). Doses of ibandronate ≥ 4.1 µg/kg/day stopped or completely reversed bone loss. Bone turnover (activation frequency) was significantly depressed in OHX dogs given ibandronate at the dose of 14 µg/kg/day. This was accompanied by significantly higher crystal size, a higher mineral-tomatrix ratio, and a more uniformly mineralized bone matrix than in control dogs. This finding lends support to the hypothesis that an increase in secondary mineralization plays a role in gain in BMD associated with bisphosphonate treatment. Moreover, intermittent and continuous therapies had a similar effect on bone volume. However, intermittent therapy was more sparing on bone turnover and bone mineral properties. Intermittent therapy could therefore represent an attractive alternative approach to continuous therapy. (J Bone Miner Res 1999;14: 1768-1778)
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