View clinical trials related to Craniofacial Abnormalities.
Filter by:The purpose of this study is to determine whether patient-specific computer-aided design (CAD) and three-dimensional (3D) printing can be utilized to produce personalized, effective continuous positive airway pressure (CPAP) masks for children with severe obstructive sleep apnea (OSA) and craniofacial anomalies who encounter significant difficulty using CPAP because of poorly fitting masks despite exhausting available commercial mask options.
An exploratory phase 2 therapeutic trial in children from 6 to 21, RTS carriers, randomized to be treated either with sodium valproate with the usual pediatric dosage (30 mg/kg/j), or by placebo for one year. The investigator would like to include children because they could best profit from it due to their neuronal plasticity as CBP and EP300 take effect through neuronal and synaptic plasticity. The therapeutic effect of sodium valproate in RTS patients will be assessed thanks to a clinical approach (learning and memory neuropsychological evaluation, fine motor skills assessment by pointing), to a biological approach (histone acetylation functional tests), and to imaging (morphological and functional MRI).
The purpose of this study is to find out if there are any genetic differences between people with and without disorders of the head, face, and eye. We will create a biorepository of samples from people with and without these types of birth defects. A biorepository is a collection or "bank" of human tissue materials (such as blood or saliva) for research purposes. These samples will then be available to investigators studying these disorders.
Part I was a double-blind, randomized, vehicle-controlled Proof of Concept (PoC) study to evaluate the safety, local tolerability, pharmacokinetics and pharmacodynamics of multiple topical administrations of LDE225 (a specific Smoothened inhibitor) on skin basal cell carcinomas in Gorlin's syndrome patients. Following a 21-day screening period, patients were exposed to multiple doses of topically applied LDE225 twice daily for 4 weeks in a double-blind manner. The patients returned weekly for visits where each BCC was clinically evaluated and digital photographs taken. Local safety and tolerability was also assessed. After the last application of treatment, biopsies were taken from treated (both vehicle and LDE225) BCCs (three per patient) for histology, biomarker evaluation and for pharmacokinetics (skin exposure). In addition, a biopsy from LDE225-treated uninvolved perilesional skin was taken for pharmacokinetic evaluation. In total, 4 biopsies were taken: 2 for histology and biomarker and 2 for PK. Part II of this study consisted of a 21-day screening period, a baseline period (directly before commencing the treatment period) and a treatment period of 6 or 9 weeks, depending on randomization. A clinical assessment was performed on site on the last treatment day and if a full clinical response had been observed, approximately 3 weeks after the last treatment an excision of the BCC(s) would have been performed. The study completion visit occurred either 1 week after the excision (when this visit was planned) or 1 week after the last treatment. For a subset of patients, skin biopsies were collected on the last treatment day and an excision of a BCC was also performed at that same visit.
This study will determine whether all patients with craniofrontonasal syndrome (CFNS) have a mutation of a gene called ephrin-B1 (EFNB1). CFNS is one of a group of conditions called craniosynostosis syndromes that result from closure of one or more of the fibrous joints between the bones of the skull before brain growth is complete. Because of the premature closure, the brain is not able to grow in its natural shape; instead, there is growth in areas of the skull where the joints have not yet closed. In CFNS, it results in malformation of the skull and face. It is known that the EFNB1 mutation can cause CFNS, and this study will see if the gene change is present in all patients with the disorder. This study includes patients and family members affected with CFNS. Participants have 1 to 2 teaspoons of blood drawn for genetic studies. A second blood sample may be requested for further research. Some blood may be used to establish a cell line for later studies. This involves growing the white blood cells from the blood sample. The cells can be kept in the laboratory to make more DNA or can be frozen for later use in studies of craniosynostosis. Patients may also have their medical records reviewed to relate gene changes to clinical features in CFNS.
Ehlers-Danlos syndrome vascular type (EDS-IV) is caused by a genetic defect of collagen type III. Patient die (median 40 yrs) of vascular complications. There is no treatment. We showed that arteries are thin and overloaded in this patients. We test the protective effect of celiprolol on cardiovascular events in a 5 years, randomized, PROBE design
This study will use stereo photogrammetry to: 1) characterize facial features of genetic and congenital malformations; 2) define facial features associated with normal growth and development; and 3) determine if stereo photogrammetry soft tissue imaging can be used to help diagnose head and facial malformations. These abnormalities currently are diagnosed using 2- or 3-dimensional skeletal images obtained with x-rays. Stereo photogrammetry uses a camera and computer to generate 3-dimensional images of the soft tissues of the face. Because the method does not use any radiation, images can be taken repeatedly to evaluate patients over a long term. Using stereo photogrammetry, images of people who belong to a defined group, for example, 17-year-old Caucasian males, can be combined (or morphed) into one image, allowing measurement of the facial features of the group. Comparing the morphed images of a normal control group with those of people with specific genetic conditions may reveal distinctions that could be used in diagnosing conditions that are currently diagnosed using x-rays. Healthy normal volunteers and patients with craniofacial dysmorphologies may be eligible for this study. Patients are recruited from current NIH studies of various genetic diseases. People who have previously had head and neck surgeries, including cosmetic surgery, may not participate. Participants give a medical and dental history, including any orthodontic work or facial surgeries. They are then positioned in front of a photogrammetry camera, a headband is placed on their head, and their picture is taken. A coded patient number is entered into the computer, where the image is stored until further analysis. Most participants are evaluated one time, but some patients and control subjects may be asked to return yearly for repeat images.
Deficient or inappropriate healing of bone impacts clinical decision-making and treatment options in orthopedics, oral and maxillofacial surgery, plastic surgery and periodontics. While a number of auto- and allografting techniques have been used to regenerate craniofacial defects caused by infective, neoplastic or trauma-induced bone loss, each method has significant limitations. Our research group in the Craniofacial and Skeletal Diseases Branch of NIDCR has developed methods to culture and expand cell populations derived from mouse bone marrow stroma. We believe that an important next step is to apply the information gained in animal studies to treat osseous defects in humans. We propose to examine the potential of cultured human bone marrow stromal cells to serve as an abundant source of osteoblastic progenitor cells. These cells will ultimately be used to graft craniofacial osseous defects. In the course of this study we will: (1) develop methods for the propagation and enrichment of osteoblastic progenitor cells from bone marrow stroma; (2) test various vehicles for the transfer of bone marrow stromal cells to osseous defects in recipient animals; (3) determine optimal culturing and transplantation conditions for the eventual transplantation of bone marrow stromal cells into human recipients. These studies will define the parameters of bone marrow stromal cell transplantation and will generate models for future therapeutic strategies.