View clinical trials related to Genetic Disease.
Filter by:For some neurological and neurodegenerative diseases genetic inheritance is well documented (described as Mendelian or multifactorial), but sometimes specific mutations or family segregation evidences have not been identified. Considering this scenario, most of the times it is impossible or unlikely to identify the responsible gene, or the private mutation, of a patient affected by a neurodegenerative disease. New technologies such as Next Generation Sequencing (NGS), allow the analysis of hundreds of genes in a single experiment. The implementation of these technologies will help to identify new genes and new variants associated with neurological diseases. Using this approach, several molecular genetic diagnosis will definitely find the needle in a haystack, and will be able to be used in the clinical practice.
Investigators aim to use comparative exome and/or genome sequencing to discover causative molecular lesions for phenotypes hypothesized to be caused by somatic mutations. For this study, investigators have targeted hypertrophic cardiomyopathy.
Background: Disturbances of the heart's atrioventricular conduction - AV-block - may show by shortness of breath, fainting or sudden death. If AV-block is diagnosed in time pacemaker therapy may be lifesaving. AV-block in younger can be seen along with structural or ischemic heart disease, congenital heart disease (incl. congenital AV-block) storage disorders, specific muscle diseases, sarcoidosis, Borrelia infection or drug intoxication. AV-block in younger can also be seen in conditions, primarily localized to the AV-node without other cardiac disease at diagnosis. This form of AV-block is often hereditary and can be seen in families where relatives have another types of heart disease in form of fore example, cardiomyopathy, ion channel disease or sudden death. The different forms of presentation are due to the same gene mutation being expressed differently within the same family. Thus, early onset of AV-block (<50 years) may indicate hereditary AV-conduction disorder but it can also be the first manifestation of severe ion channel disease or cardiomyopathy. Denmark has annually over 50 individuals <50 years treated with pacemaker due to advanced AV-block. There have been no overall figures regarding the causes of advanced AV-block, and therefore no systematic approach to diagnosing this group of patients. Furthermore, the prevalence of individuals with a genetic cause of AV-block is unknown and presumably an often overlooked diagnosis among younger patients with advanced AV-blok. There are no data on disease progression after diagnosis, and therefore there is no evidence-based knowledge about how these patients should be followed after diagnosis. With modern gene technology, a range of new, yet unknown genes with potentially pathogenic mutations is likely to be identified. Identification of such genes, and the development of a strategy for systematic approach to diagnose younger patients with AV-block, will enable presymptomatic genetic screening of relatives and implementation of evidence-based, preventive treatment with pacemaker and/or medical treatment for heart failure based on a specific genetic predisposition for development of AV-block with or without heart failure. Hypotheses: In a significant proportion of younger patients with advanced AV-block the underlying cause is unknown. Objective: To investigate the prevalence and causes of advanced AV-block in younger patients in Denmark and describe the current diagnostics. Method: The study is a cross sectional study. The patients for this study are identified from Danish Pacemaker and ICD Register. The investigators will review medical records and obtain clinical information and test results (see detailed description). Perspectives: This study is the first part of a large study of AV-block in younger patients in Denmark. The overall goal, is to increase knowledge about the causes of and disease progression after the diagnosis of advanced AV-block in young patients which could lead to a significant improvement in the treatment of this patient group and may lead to a customized choice of pacemaker type in the future and perhaps additional medical treatment in this patient group. This could potentially lead to a reduction in both their morbidity mortality.
The purpose of study is to evaluate the benefits of using the Next Generation Sequencing Technology to diagnose birth defects and genetic diseases. The results from genomic sequencing can also significantly shorten the time of examination, improve the diagnosis rate, guide the clinical treatments. So the ultimate goal is individualized or personalized therapy and promote prognosis.
The purpose of study is to evaluate the benefits of using the Next Generation Sequencing Technology to diagnose birth defects and genetic diseases. The results from genomic sequencing can also significantly shorten the time of examination, improve the diagnosis rate, guide the clinical treatments. So the ultimate goal is individualized or personalized therapy and promote prognosis.
Without an explanation for severe and sometimes life-threatening symptoms, patients and their families are left in a state of unknown. Many individuals find themselves being passed from physician to physician, undergoing countless and often repetitive tests in the hopes of finding answers and insight about what the future may hold. This long and arduous journey to find a diagnosis does not end for many patients- the Office of Rare Diseases Research (ORDR) notes that 6% of individuals seeking their assistance have an undiagnosed disorder. In 2008, the National Institutes of Health (NIH) Undiagnosed Diseases Program (UDP) was established with the goal of providing care and answers for these individuals with mysterious conditions who have long eluded diagnosis. The NIH UDP is a joint venture of the NIH ORDR, the National Human Genome Research Institute Intramural Research Program (NHGRI-IRP), and the NIH Clinical Research Center (CRC) (1-3). The goals of the NIH UDP are to: (1) provide answers for patients with undiagnosed diseases; (2) generate new knowledge about disease mechanisms; (3) assess the application of new approaches to phenotyping and the use of genomic technologies; and (4) identify potential therapeutic targets, if possible. To date, the UDP has evaluated 3300 medical records and admitted 750 individuals with rare and undiagnosed conditions to the NIH Clinical Center. The NIH UDP has identified more than 70 rare disease diagnoses and several new conditions. The success of the NIH UDP prompted the NIH Common Fund to support the establishment of a network of medical research centers, the Undiagnosed Diseases Network (UDN), for fiscal years 2013-2020. The clinical sites will perform extensive phenotyping, genetic analyses, and functional studies of potential disease-causing variants. The testing performed on patients involves medically indicated studies intended to help reach a diagnosis, as well as research investigations that include a skin biopsy, blood draws, and DNA analysis. In addition, the UDN will further the goals of the UDP by permitting the sharing of personally identifiable phenotypic and genotypic information within the network. By sharing participant information and encouraging collaboration, the UDN hopes to improve the understanding of rare conditions and advance the diagnostic process and care for individuals with undiagnosed diseases.
Collection of coded biomaterial and clinical data with patients consent for future research.
The purpose of this study is to compare the effectiveness of rapid next generation sequencing (NGS, such as whole genome sequencing1) with current practice to provide diagnostic or prognostic information or treatment guidance in acutely ill neonates and infants, particularly with respect to clinical care, cost and outcomes.
Background: - People with sickle cell disease and other blood disorders sometimes get chronic leg ulcers. These are wounds that develop on the skin and don t go away. Current treatments do not work very well, so researchers want to learn more about why the ulcers happen. They want to find out which bacteria may cause it, and if external factors play a role. Objective: - To study social and environmental factors of sickle cell disease and the causes of sickle cell disease leg ulcers. Eligibility: - People age 18 and older who have sickle cell disease or another red cell disorder, with or without an active leg ulcer. Design: - Participants will have a medical history and clinical evaluation. They will also have blood drawn. - Participants will complete questionnaires about their life, health, environment, stress, and other topics. - Participants may provide a small sample of hair. - Participants will be asked to collect a small amount of saliva. - Participants with leg ulcers will have their skin microbiome sampled. The microbiome is all of the microbes (bacteria and and/or fungi) and their genes in and on the body. Researchers will use swabs to collect skin samples. Photographs will be taken of the skin sample area. - Some participants without leg ulcers also will have their skin microbiome sampled. - Some participants who have their skin microbiome sampled will return for a second visit. At this visit, their microbiome will be resampled. It will take place more than 30 days after the first visit.
The aim of the research is to investigate the safety and efficacy of EPI-743 treatment in patients with Cbl-C defect and related visual and neurological impairment. Primary Endpoints will be the improvement in visual function as assessed by visual acuity and eye-hand coordination and manual dexterity. Secondary Endpoints will be the improvement in neurologic function, evaluated by a battery of age-appropriated psychophysical tests, and/or in objective electrophysiological tests such as Visual Evoked potentials (VEP) and Electroretinogram (ERG) and/or the change in serum markers of redox state.