View clinical trials related to Bone Strength.
Filter by:Exposure to vitamin D intervention in early life may have permanent effects on physiology and metabolism. Bone growth and mineralization, development of immunity, body composition and brain structure and functioning may be affected. The importance of a long-term surveillance includes follow-up of both beneficial but also harmful effects of vitamin D. Vitamin D intervention in infants (VIDI) study was conducted in 2013-2016. VIDI study was a large randomized trial that aimed to evaluate effects of two vitamin D supplemental doses of daily 10 ug and 30 ug from the age 2 weeks until 2 years on bone strength, infections, immunity, allergy, atopy and asthma, neurologic and cognitive development, and genetic regulation of mineral homeostasis. Current study is a 6 Years Follow-up (VIDI2) study of the original VIDI trial. Our focuses of interest in the follow-up are: bone strength, growth pattern, body composition, and morbidity due to infections and allergic diseases, and the development of immunity. Further, in addition to more classical associates of vitamin D, our aim is to continue to follow-up children's neurocognitive development and mental health. We will also focus on the effect of vitamin D supplementation on occurrence of molar-incisor hypomineralization, dental caries, and oral immunity.
Osteoporotic fractures are an extremely common and serious public health issue which contribute substantially to pain, impaired mobility and morbidity in the elderly. Declines in bone strength combined with an increase risk of falls (associated with decline in muscular function with age) are the main determinants of fracture risk. Exercise that is novel and involves impact loading has the potential to improve bone strength and neuromuscular function (strength, power and balance). It is thus imperative to evaluate potential benefits of exercise in older people. The musculoskeletal responses to exercise may also be influenced by vitamin D status. It is the purpose of this study to consider the influence of a one year unilateral (one limb) high impact exercise programme on musculoskeletal health, specifically bone structure, muscle strength and power in older caucasian men. It is also the purpose of this study to determine whether this differs according to vitamin D status. The findings will reveal whether exercise can improve bone health and/or neuromuscular function, and whether improvements are dependent upon vitamin D status.
Treatment for childhood cancer interferes with normal bone maturation such that maximal peak bone mass may never be attained by some survivors of childhood cancer. In childhood cancer survivors, a randomized trial evaluating the effectiveness of vitamin D and calcium supplementation among ALL survivors is currently underway; however, few other interventions have been offered for this at risk population. Recent evidence demonstrates that low magnitude; high frequency mechanical stimulation can improve bone quantity and quality, perhaps providing an alternative or adjunct to pharmacologic intervention in populations where additional medications are either contraindicated or not acceptable to the individuals at risk. This application proposes a prospective double blind randomized clinical trial of low magnitude, high frequency mechanical (LMHF) stimulation for childhood cancer survivors whose bone mineral density is one or more standard deviations below the mean for their age and gender.
Stress fractures are a common and debilitating injury for a variety of athletes however current evidence does not clearly allow easy prediction of athletes at risk for a first fracture. Animal and some preliminary human evidence suggest that assessment of bone strength, muscle size and running mechanics may be primary risk factors for stress fractures. The investigators study will help determine which, if any, of these modifiable risk factors could help identify athletes at risk for stress fracture. Competitive female distance runners will be recruited for this study. Participants will placed into a stress fracture or control group based on stress fracture history. Dual energy x-ray absorptiometry (DXA) and peripheral Quantitative Computed Tomography (pQCT) will be used to assess bone structure and strength. Running mechanics will be assessed during a 30-40 minute fatiguing run. A treadmill with an embedded force plate and high speed video will be used to assess changes in running mechanics throughout the run. The purpose of this project will be to 1. explore differences in volumetric bone mineral density (vBMD), bone geometry, and muscle cross sectional area (MCSA) using pQCT 2. explore changes in load (GRFs) and running mechanics that occur during a fatiguing run in runners with and without a history of stress fracture.