View clinical trials related to Bone Disorder.
Filter by:The aim of this project is to set up a biological and clinical collection of patients with progressive bone, calcium and growth plate pathologies. This collection will provide a better understanding of the mechanisms involved in growth plate and bone damage in these diseases and identify factors predictive of progression and new therapeutic targets.
The optimal management of mineral and bone disorders associated to chronic kidney disease (CKD-MBD) is a daily challenge for nephrologists. Its consequences may be immediate (biological abnormalities such as hypocalcemia, hyperphosphatemia, hyperparathyroidism, etc.) or delayed (fractures, renal osteodystrophy, vascular calcifications, increased morbi-mortality and growth retardation in the youngest patients). CKD-MBD is defined by the association of one or more of the following abnormalities: 1/ disturbances in calcium, phosphate, PTH or vitamin D metabolism, 2/ bone and growth abnormalities, and 3/ calcifications of vessels or soft tissues . Three main bone characteristics can be modified by CKD, namely turnover, mineralization and volume. They should therefore be carefully assessed to distinguish between the different sub-types of renal osteodystrophy, as defined in the 2006 K-DIGO guidelines on the TMV classification . The primary bone lesion in pediatric CKD, at least in pediatric patients reaching end-stage renal disease without any previous management, is the high-turnover/hyperparathyroidism, because of high circulating PTH levels with low 1-25 vitamin D levels. Conversely, low turnover (or adynamic bone) may be observed in dialysis children receiving too much calcium and/or vitamin D analogs. All these lesions are deleterious on the long-term, increasing both the risk of growth retardation, fractures and vascular calcifications . In order to better understand the complex pathophysiology of renal osteodystrophy, biomarkers of bone and phosphate/calcium metabolism may be used, but their interpretation may be challenging in the context of CKD. The gold standard remains bone biopsy at the iliac crest with histomorphometry, but it is rarely performed in Europe . The research team of this study has developed and validated a unique non-invasive technique to differentiate circulating human monocytes into mature and functional osteoclasts, using only 15 mL of total blood (instead of conventional techniques they used to use, with 200 to 250 mL of total blood). They propose to use this innovative tool in the specific setting of CKD. The current management of CKD-MBD consists mainly of correcting native vitamin D deficiency, decreasing phosphate levels (using nutritional management and phosphate-binders), and decreasing PTH levels (using active vitamin D, calcimimetics such as cinacalcet and etelcalcetide, and/or surgical parathyroidectomy) . Active vitamin D analogs and calcimimetics are cornerstone of this management. The first working hypothesis is the following: when CKD progresses and glomerular filtration rate (GFR) decreases, 1-25-D is able to inhibit osteoclastic differentiation, however to a lesser extent to what is observed in healthy controls with normal renal function. The second working hypothesis is therefore the following: etecalcetide could be an inhibitor of osteoclastic resorption and a stimulator of osteoblastogenesis. When CKD worsens and GFR decreases, etelcalcetide inhibits osteoclastic differentiation, however to a lesser extent to what is observed in subjects with normal renal function. Aims In Vitro 1. Effects of 1-25-D and etecalcetide on human osteoclastogenesis and osteoclastic resorption (in cells obtained from CKD patients at different stages of CKD) 2. Effects of 1-25-D and etecalcetide on murine osteoblastogenesis and mineralization
The researcher wants to explore the genetic causes of muscle disease. The researcher is particularly interested in muscle disorders that occur in combination with diseases of bone that appear to be passed on from generation to generation. Diffuse Optical Spectroscopy will measure the concentrations of blood, water, and lipids (fats, for example) in your tissues. This device essentially measures the color of tissues in order to determine tissue physiology (its physical and chemical processes).