Active clinical trials for "Fibrous Dysplasia of Bone"

Background: Fibrous dysplasia (FD) is a disease that affects the bones. It causes bone lesions that can become weak and lead to fractures, deformity, and nerve injuries. FD bone lesions begin to develop soon after birth and grow during childhood. The lesions stop growing in adults but can still cause disability. Researchers want to find ways to stop the growth of FD bone lesions. Objective: To test a study drug (denosumab) in children with FD. Eligibility: Children aged 4 to 14 years with FD and who are also enrolled in the Screening and Natural History protocol (98-D-0145). Design: Participants will have a screening visit at the NIH clinic or by telehealth. Their medical history will be reviewed. Participants will stay overnight in the hospital 4 times in 76 weeks. Each stay will last 5 to 7 nights. Participants will also visit a local lab for blood and urine tests every 4 weeks during the study. Participants will receive denosumab once every 4 weeks for 48 weeks. The medication is given as a shot injected under the skin using a small needle. Some injections may be performed at home by a caregiver. The caregiver will receive training for this procedure. Participants will undergo many tests that may be repeated throughout the study. They will have a dental exam. They will have tests of their strength and ability to move freely. They will have x-rays and other scans to get pictures of their bones. Participants will be given another medicine that is administered through a needle in the arm over 30 minutes.

Fibrous Dysplasia/McCune-Albright syndrome (FD/MAS) is a rare disease, consisting of the replacement of normal bone tissue with fibrous tissue. FD lesions may be isolated in one or more bones or may be associated with endocrinopathies in McCune-Albright syndrome. Bone lesions constitute of weak bone tissue, leading to higher risk of fractures, pain and decreased quality of life. There is no cure for FD lesions and current therapies failed to soothe patients' complaints or to display any effect on progression of the lesions on imaging. However, the RANKL-inhibitor Denosumab demonstrated encouraging results in mouse models and in off-label clinical use, leading to clinical, biochemical and radiographical improvements. Study's aim is to investigate whether 3-monthly Denosumab will improve the clinical, radiological and biochemical manifestations of FD bone lesions.

Background: Fibrous dysplasia (FD) is a disorder that affects bone growth. Affected bone tissue is weakened, and people with FD are prone to deformities, fractures, and other problems. People with FD may also have low blood phosphate levels. This can make bones even weaker. Better treatments are needed. Objective: To test a study drug (burosumab) in people with FD who have low blood phosphate levels. Eligibility: People aged 1 year or older who have FD and low blood phosphate levels. Design: Participants will visit the NIH 3 times in 48 weeks. Each visit will last 5 to 7 days. Participants will self-inject burosumab under the skin in their belly, upper arm, or thigh. They (or a caregiver) will do this at home 1 or 2 times a month. They will be trained in person on how to inject the drug. Home injections will be guided via telehealth. During NIH visits, participants will have a physical exam with blood and urine tests. They will have x-rays of different parts of their body. They will have a radioactive tracer injected into their vein; then they will have a bone scan. They will have tests to assess their strength, walking, and movement. They will complete questionnaires about their pain, mobility, and fatigue levels. Adult participants may have bone biopsies. These will be done under anesthesia with sedation. Small samples of FD-affected bone will be removed for study. Between NIH visits, participants will go to a local laboratory for blood and urine tests. Child participants will have an additional follow-up visit 2 weeks after the final NIH visit.

Objectives: The primary objective of this study is to evaluate the effect of denosumab on bone turnover in individuals with fibrous dysplasia (FD). Secondary objectives are to determine the effect of denosumab on bone pain, FD lesion intensity as revealed in 18F-sodium fluoride PET/CT bone scan, and to determine the effect of denosumab discontinuation on bone turnover re-bound after discontinuation. Study Population: Up to 14 adult subjects with FD may be enrolled to ensure complete study data on 9 subjects. Design: This study is a single center, open label pilot study of once-monthly dosing of denosumab. Subjects will be treated for 6 months, after which they will be followed by an 8-month observation period. A final visit will occur 21 months after denosumab discontinuation. Dosing will be adopted from studies in adults on treatment for giant cell tumors, with denosumab administered at 120 mg per dose every 4 weeks, with loading doses on days 7 and 14 of month 1. Outcome Measures: Primary: Assessment of the effects of denosumab on: 1. Markers of bone turnover: Beta-crosslaps C-telopeptides (bone resorption marker) Procollagen-1-propeptide (bone formation marker) Secondary: Assessment of the effects of denosumab on: Bone histomorphometric indices: Mineralized perimeter Bone formation rate Cortical width Cortical area Osteoid width Osteoid perimeter Mineral apposition rate Surrogate markers of a direct therapeutic effect of denosumab on FD lesions: Semi-quantitative changes in RANKL, Ki67 (marker of cell proliferation), p16 (marker of cell senescence), and/or apoptosis index before and after treatment, as assessed by immunohistochemistry Changes in sentinel lesion intensity, measured quantitatively by uptake on 18Fsodium fluoride PET/CT bone scan. FD-related bone pain assessed by the Brief Pain Inventory (Short Form) , a validated self-reporting tool for assessment of pain. Exploratory Endpoints: Effect of denosumab initiation and discontinuation on Serum calcium, phosphorus and parathyroid hormone Serum RANKL and osteoprotegerin (OPG), and RANKL/OPG levels Effect of denosumab discontinuation, as measured by the following outcomes: Biochemical markers of bone metabolism: beta-crosslaps C-telopeptides, procollagen-1 propeptide, bone specific alkaline phosphatase, osteocalcin, NTX-telopeptides Effect measured by change in other outcome measures, such as: Bone density assessed by DXA Physical Medicine and Rehabilitation evaluation

Pain remains a common and frequently debilitating symptom, particularly during adulthood of Fibrous Dysplasia/McCune-Albright Syndrome (FD/MAS). For many FD/MAS patients, the amount of pain perceived is not commensurate with the level of detectable musculoskeletal pathology. Using a combination of clinical and biological assessments, this investigation aims to understand what drives pain in FD/MAS.

Fibrous dysplasia of bone is a rare congenital but non-hereditary disease caused by a post-zygotic activation mutation of the GNAS gene. Patients with fibrous dysplasia may present pain and bone complications (fractures, deformities..) related to their bone lesions. For undetermined reasons, severity and disease evolution may vary considerably from patient to patient. Epigenetic regulation could then be involved, including micro Ribonucleic Acids (miRs). These small non-coding micro Ribonucleic Acids are involved in the regulation of major steps of cellular processes in different pathologies, in particular in bone diseases. However, micro Ribonucleic Acids have never been studied in fibrous dysplasia. The aim of this study is to identify micro Ribonucleic Acids significantly associated with the severity of fibrous dysplasia.

Polyostotic fibrous dysplasia (PFD) is a sporadic disorder which affects multiple sites in the skeleton. The bone at these sites is rapidly resorbed and replaced by abnormal fibrous tissue or mechanically abnormal bone. PFD may occur alone or as part of the McCune-Albright Syndrome (MAS), a syndrome originally defined by the triad of PFD, cafe-au-lait pigmentation of the skin, and precocious puberty. The bony lesions are frequently disfiguring, disabling and painful, and depending on the location of the lesion, can cause significant morbidity. Lesions in weight-bearing bones can lead to disabling fractures, while lesions in the skull can lead to compression of vital structures such as cranial nerves. The natural history of this disease is poorly described and there are no clearly defined systemic therapies for the bone disease. This is a data collection and specimen acquisition protocol. The purpose of the study is to define the natural history of the disease by following PFD/MAS subjects over time and by using in vitro experimentation with samples/tissue from subjects with the disease. Study Objectives Primary Objective Define the natural history of disease by gaining clinical and basic information about PFD/MAS by following subjects clinically and using in vitro experimentation with tissue from subjects with the disease. Secondary Objective Refer eligible subjects for enrollment into other appropriate research protocols, if any are currently active. Study Population The study population will include: Subjects with known or suspected Polyostotic Fibrous Dysplasia (PFD) or in combination with McCune-Albright Syndrome (MAS) Subjects who meet eligibility criteria will be accepted regardless of gender, race, or ethnicity Design This study is an observational/natural history study of PFD/MAS. Outcome Measures Primary Successfully enroll subjects with PFD or MAS for the collection, evaluation and analysis of data obtained from clinical visits. Obtain onsite and offsite research tissue (waste tissue) from patients with PFD/MAS that are enrolled onto this study or from individuals with PFD/MAS that are offsite and willing to donate waste tissue to NIH. Research tissue will be used with existing primary cell culture technology (ongoing in our laboratories) to: understand the basic bone biology of the pathologic cell (or cells) involved in the lesions of PFD/MAS determine the presence or absence of mutated cells at "uninvolved sites" to formulate better strategies of predicting the initiation of new lesions, the natural history of lesion progression and/or response to therapy understand osteogenic differentiation, in particular, the role of G(s)alpha in these lesions, which will be transferable to our understanding of bone biology in general understand the pathophysiology of FD and/or endocrine lesions develop better methods of identifying and expanding unaffected bone cells from patients with PFD in an effort to create better grafting material(s) Identify and predict clinical and biological behavior of fibrous dysplastic bone lesions based on: stability, rate of growth, rate of change, progression and regression, and development of new lesions differences between cranial, axial and appendicular lesions Define the natural history of the multiple endocrinopathies associated with MAS and the response to standard of care medications Define clinical and biological aspects of the disease not previously identified Generate future research studies related to PFD alone or in combination with MAS Secondary 1) Successfully enroll eligible subjects into active research protocols applicable to the FD/MAS population....

This study will address medical devices manufactured by Biomet Microfixation (d.b.a. Zimmer Biomet) designed for fixation and stabilization of the facial and mandibular skeleton.

The FD/MAS Patient Registry is an IRB-approved research study that that invites the patients and families to help answer some of the biggest questions about FD/MAS by completing questionnaires about their lives with FD or MAS. Have you enrolled in the FD/MAS Patient Registry yet? Are you up-to-date on your surveys? Take a trip to www.fdmasregistry.org today to learn more about the project, enroll, complete your surveys, or make sure you aren't due to provide more info! The FD/MAS Patient Registry: Your story powers research.

The normal changes of puberty, such as breast enlargement, pubic hair and menstrual periods, usually begin between the ages of 9 and 15 in response to hormones produced in the body. Some children's bodies produce these hormones before the normal age and start puberty too early. This condition is known as precocious puberty. The hormones responsible for the onset of puberty come from the pituitary gland and the ovaries. The hormones from the pituitary gland act on the ovaries to produce different hormones that cause the breasts to grow, pubic hair to develop, and menstruation. Many children with precocious puberty can be treated with a medication known as lutenizing hormone-releasing hormone analog (Lupron, Histerelin, Deslorelin). This drug is made in a laboratory and is designed to act like the natural hormone LHRH, which is made in the pituitary gland. The drug causes the pituitary gland to decrease the amount of hormones it is releasing and thereby decrease the amount of hormones released by the ovaries. However, some girls already have low levels of pituitary hormones and yet their ovaries still produce hormones. Researchers do not believe that LHRH analog therapy will work for these children. Testolactone is a drug that acts directly on the ovary. It works by preventing the last step of estrogen production in the ovary. The goal of this treatment is to stop estrogen production and delay the onset of puberty until the normal age. Researchers will give patients with LHRHa resistant precocious puberty Testolactone for six months. If the initial treatment is successful and patients do not experience very bad side effects, they will continue to receive the medication until puberty is desired. Throughout the therapy patients will receive frequent monitoring of their general state of health, hormone levels, and medication levels.