View clinical trials related to Genetic Disease.
Filter by:This study aims to evaluate the electrophysiological properties of the heart conduction system in patients with unexplained polymorphic ventricular tachycardia (VT) and/or ventricular fibrillation (VF), in patients with specific genetic mutations regarding sudden cardiac death or sudden cardiac arrest, in their family members and in a control cohort. The electrophysiological properties will be measured with the relatively new technique ECG-Imaging (ECGI). Also a National Dutch registry for patients with unexplained polymorphic VT and/or VF and their family members will be created. By combining the data from the registry and the results of ECGI, The investigators hope to identity risk markers for patients at higher risk for apparently idiopathic ventricular fibrillation, and use these for an adapted flow chart for the 'general'population of patients at risk for unexplained polymorphic VT and/or VF. The investigators aim to be able to identify patients before the first arrhythmic event, and aim for better treatment strategies in the future.
This is a pilot study involving a prospective group of 15 evaluable patients who will undergo rapid whole genome sequencing in addition to standard of care testing. Subjects will be drawn from children admitted to the NICU at OSF Health Care Children's Hospital of Illinois who meet inclusion criteria. The aims of this study are to evaluate the turn-around time and cost of performing rapid whole genome sequencing (rWGS) compared to standard of care in the diagnosis of genetic disorders among critically ill infants in a regional children's hospital and to describe management outcomes of utilizing rWGS in acutely ill patients less than four months of age.
Phenotypic characterisation of MVP by echocardiography in families. Identification of genes involved in MVP.
The primary hypothesis is that a tailored programme of genetic and imaging screening of first- and second-degree relatives of patients affected by non-syndromic forms of thoracic aortic diseases will identify individuals at risk of death from these conditions. These individuals would constitute specific population of patients, requiring dedicated imaging surveillance and/or earlier prophylactic aortic surgery.
The purpose of this study is to evaluate the efficacy and safety of DCR-PHXC in Children and Adults with Primary Hyperoxaluria Type 1 (PH1) and Primary Hyperoxaluria Type 2 (PH2)
The need for new models of integrated care that can improve the efficiency of healthcare and reduce the costs are key priorities for health systems across the United States. Treatment costs for patients with at least one chronic medical or cardiovascular condition make up over 4-trillion dollars in spending on healthcare, with estimations of a population prevalence of 100-million affected individuals within the next decade. Therefore, the management of chronic conditions requires innovative and new implementation methods that improve outcomes, reduce costs, and increase healthcare efficiencies. Digital health, the use of mobile computing and communication technologies as an integral new models of care is seen as one potential solution. Despite the potential applications, there is limited data to support that new technologies improve healthcare outcomes. To do so requires; 1) robust methods to determine the impact of new technologies on healthcare outcomes and costs; and 2) evaluative mechanisms for how new devices are integrated into patient care. In this regard, the proposed clinical trial aims to advance the investigator's knowledge and to demonstrate the pragmatic utilization of new technologies within a learning healthcare system providing services to high-risk patient populations.
As part of this study patients who have undergone genetic testing in the Brigham and Women's Hospital Cardiovascular Genetics program will be randomized to receive the results of their genetic testing either by telephone call or virtual visit. At the completion of the telephone call or virtual visit patients will receive a survey to assess their understanding of their results and their satisfaction with their care.
Studies have shown that the risk of developing heart arrhythmias, is increased in patients receiving medication for Attention-deficit hyperactivity disorder (ADHD) and depression. The QT-interval on a electrocardiogram (ECG) is often used to assess the patients risk of developing heart arrhythmias. The QT-interval defines the hearts electrical resting period and a long interval is linked to an increased risk of developing heart arrhythmias. In this project the investigators wish to examine possible side-effects in patients receiving medication for ADHD and depression and their dynamic QT-interval changes, by analysing the ECG changes that occur during "Brisk Standing".
In this study, we will conduct retrospective chart and imaging reviews and prospective longitudinal virtual assessments of individuals with LBSL.
Recent advances have shown that cells from human blood, skin and urine samples can be reprogrammed to become stem cells. These are called induced Pluripotent Stem Cells (iPSCs) and share many characteristics with embryonic stem cells, including an unlimited capacity for proliferation and the potential to become any cell in the body. Beneficially, the use of iPSCs avoids the ethical difficulties which surround embryonic stem cells and allows generation of iPSC lines which are disease representative. For example, we could take skin samples from an individual diagnosed with Huntington's disease and their unaffected sibling and using this technology, generate iPSC lines from both individuals. Using these iPSCs, we could produce disease affected cell populations from the affected and unaffected individuals, use these cells to research why specific cell populations are affected by disease and test new treatments to combat disease progression, essentially producing a 'disease in a dish'. This is just one example of many for which this technology could be applied. We can also utilise gene-editing techniques to generate isogenic controls or insert disease related mutations to assess disease phenotype. Although generation of iPSC lines has been robustly proven across multiple disease backgrounds, many aspects of their downstream use still remain to be determined. Particularly, robust protocols for directing iPSCs towards cell fates such as neurons or blood cells must be developed to fully realise application of iPSCs in disease modelling and drug screening. This study involves the collection of human blood, skin or urine samples from subjects bearing a range of genetic diseases alongside those from individuals who have not been diagnosed with a disease, as controls. These samples will be used to generate iPSC lines for development of differentiation and disease phenotyping protocols.