View clinical trials related to Osteoporosis.
Filter by:This study is designed to evaluate the efficacy and safety of zoledronic acid 5 mg intravenous (i.v.) relative to placebo in Multiple Sclerosis (MS) patients with osteoporosis and to support the optimal use of zoledronic acid for this indication. Primary objective is the change of Bone Mineral Density (BMD) at lumbar spine (L1-L4) and total hip region assessed by T-Score at month 12 relative to screening as measured by Dual X-ray Absorptiometry (DXA). This double-blind period will be followed by a 52-week open-label treatment phase to assess long-term efficacy and safety of zoledronic acid in these patients.
Resistance training as well as creatine supplementation may increase bone mass. Therefore, the investigators speculate that resistance training combined with creatine supplementation would promote additive benefits on bone mass in elderly women with osteopenia and osteoporosis.
This project will examine the current diagnosis and treatment of bone health in patients with obstructive airway disease. Patients will be referred to The Osteoporosis Centre of BC (OCBC) by their respirologist to be assessed for osteoporosis including Dual Energy Xray Absorptiometry (DXA) scan. Previous chest xrays and will be accessed and examined for vertebral fractures, diagnostic of osteoporosis. The lung and bone data will be entered into a database. This will allow us to explore the relationship of lung disease parameters to osteoporosis predictors, eventually determining a respirology patient population who are at high risk of fracture. Longitudinal evaluation of bone health and its relationship to respiratory parameters over time will be explored by follow-up evaluations at 12 and 24 months.
Study to Characterize the Safety, Pharmacokinetics, and Pharmacodynamics of CEP-37251 in Healthy Postmenopausal Women.
This study will investigate the effects on bone quality of a medication (Teriparatide) used to treat people with severe osteoporosis. Teriparatide is the only bone formation therapy that has been approved for the treatment of postmenopausal osteoporosis in Canada. Osteoporosis is currently diagnosed using a bone mineral density (BMD) scan, which measures the amount of mineral (calcium etc) in bones (the higher the amount of mineral, the lower the fracture risk). Although BMD is linked to bone strength and is used to measure fracture risk, it does not give information on bone structure (called bone geometry) which can also tell us a great deal about fracture risks. Clinical trials have shown that teriparatide increases BMD at the lumbar spine and total hip, while BMD at the forearm decreases after 20 months of therapy. Whether this decrease of BMD at the forearm suggests a higher risk of wrist fracture or a change in bone structure is unclear. Bone biopsies of the pelvis done on people taking teriparatide shows improvement of bone geometry (ie bone thickness and increased trabeculae (small interconnecting rods of bone), suggesting that a change in bone geometry at the wrist may be occurring as well. Currently, there is a new technology, high resolution pQCT (HR-pQCT) that can assess bone geometry without a biopsy. Since bone strength is affected both by BMD and bone structure (as well as other material properties), our group is interested in examining changes in bone geometry at the forearm (a non-weight bearing site) and ankle (a weight bearing site) in postmenopausal women with osteoporosis who receive 24 months of teriparatide therapy. The investigators believe that this new approach of measuring bone strength will help us better understand whether teriparatide has different effects at different bone sites.
Teriparatide (PTH) is the only bone formation therapy that has been approved for the treatment of postmenopausal osteoporosis in Canada. Osteoporosis is currently diagnosed using a bone mineral density (BMD) scan, which measures the amount of mineral (calcium etc) in bones (the higher the amount of mineral, the lower the fracture risk). Although BMD is linked to bone strength and is used to measure fracture risk, it does not give information on bone structure (called bone geometry) which can also tell us a great deal about fracture risks. Clinical trials have shown that teriparatide increases BMD at the lumbar spine and total hip, while BMD at the forearm may decrease after 20 months of therapy. However, bone biopsies of the pelvis done on people taking teriparatide show improvement of bone geometry (ie bone thickness and increased trabeculae (small interconnecting rods of bone), suggesting that a change in bone geometry at the wrist may be occurring as well. Currently, there is a new technology, high resolution pQCT (HR-pQCT) that can assess bone geometry without a biopsy. Since bone strength is affected both by BMD and bone structure (as well as other material properties), our group is interested in examining changes in bone geometry at the radius and tibia in men and women with osteoporosis who receives 24 months of teriparatide therapy. The investigators believe that this new approach of measuring bone strength will help us better understand the mechanisms of therapeutic efficacy of teriparatide. In addition, measuring indices of bone strength such as the material composition (bone mineral content or BMD) and structural properties of bone (size and shape, and microarchitecture) may provide more data about the mechanisms of how teriparatide treatment can decrease fracture risk. In the end, this data will benefit and improve patient care by allowing us to show patients and their providers that whether BMD increases, decreases or stay the same, there are changes in their bone geometric structure with teriparatide therapy that increases bone strength.
Vitamin D is a hormone that is produced when sunlight is absorbed by the skin. Vitamin D insufficiency has been recognized as a problem in areas where sun exposure is limited, especially in the wintertime. In addition, the more pigmented the skin is, the less capable it is of utilizing sunlight to make vitamin D. Vitamin D plays an important role in helping the body absorb calcium and in building strong bones. It has also been shown to improve muscle function in the elderly. As we get older, our vitamin D levels in the blood go down and this may increase the risk for falls and fractures. If we can improve vitamin D status as we age, we may be able to improve muscle strength and decrease the risk of falls and fractures.
The purpose of this study is to apply a novel advanced magnetic resonance imaging methodology to evaluate the response to drug intervention involving two treatment arms of postmenopausal participants with osteoporosis, randomized into either a teriparatide (Forteo™) or zoledronic acid (Reclast™) group.
Osteoporosis is one of the most common skeletal disorders. Today in the United States, 10 million individuals have osteoporosis and 34 million more have low bone mass or osteopenia, which places them at an increased risk of some day developing osteoporosis. Of the people affected by this problem, 68% are women.The current thinking on the development of osteoporosis is that the changes in bone turnover that occur with aging play a major factor. Many modalities of treatment are used to prevent the bone loss and increased fracture risk associated with osteoporosis and osteopenia. Melatonin supplementation may be another treatment modality that lowers risk of hip fracture in perimenopausal women. Melatonin can remodel bone in animal models and in culture. Melatonin works through melatonin receptors to form osteoblasts from human mesenchymal stem cells and has been shown to inhibit osteoclast activity in rodents. Melatonin levels have been correlated with modulating bone markers; low nocturnal levels of melatonin correlate with in an increase in bone marker metabolism and osteoporosis. It is been shown that women who have worked night-shifts for greater than 20 years have increased risk for wrist and hip fractures. Night-shift workers have lower nocturnal melatonin levels than people who do not work the night-shift. The addition of exogenous melatonin suppresses bone marker metabolism. In human stem cells taken from bone marrow, melatonin increases the activity of bone-forming cells called osteoblasts. It is hypothesized that melatonin will improve bone health, menopausal quality of life and sleep compared to placebo in perimenopausal women. In particular, the investigators expect perimenopausal women taking melatonin to show an improvement in overall bone health as revealed by a reduction in bone marker turnover since bone resorption increases more so than bone absorption in this population compared to those women taking placebo. We also expect that perimenopausal women taking melatonin to have better control over their menopausal symptoms, better quality of life and less sleep disturbances when compared to their placebo controls since melatonin is known to modulate estrogen levels in the body and regulate sleep. The data from these studies may provide novel and alternative uses for melatonin; in particular its use for the prevention and/or treatment of osteoporosis.
The NCIC CTG was conducting an international breast cancer prevention trial (MAP.3) examining the effects of a new therapy (exemestane) for breast cancer prevention in postmenopausal women at increased risk of developing this disease. Results showed that after a median follow up of 35 months, exemestane was superior to placebo in breast cancer prevention. Exemestane blocks estrogen production, which may be beneficial for preventing breast cancer, but may have negative effects on bone. As postmenopausal women are at risk for developing osteoporosis, determining whether exemestane causes bones to weaken is crucial for women considering it for long-term use. Dr. Cheung's team followed the bone health of 354 women in MAP.3 in detail over 2 years and found that volumetric bone mineral density (by high resolution peripheral quantitative computer tomography (HR-pQCT) at the radius and tibia as well as areal bone mineral density by dual energy x-ray absorptiometry (DXA) at the hip and spine decreased significantly with the use of exemestane. The long term effects of exemestane on bone will be examined up to 5 years of therapy and then 2 years post therapy to delineate the effects of exemestane on bone strength. This research will inform us on the safety of exemestane for breast cancer prevention.