Active clinical trials for "Genetic Diseases, Inborn"

To learn about patient barriers to accessing genetic medicine, we will analyze anonymous posts from a membership-based online community [Inspire.com], and investigate how these barriers differ for various populations. We will then test whether these barriers can be addressed by providing online access to a genetic counselor to answer patient questions for one group of patients (virtual advisory board group) and compare to that of a control group who does not have access to a genetic counselor (virtual peer-to-peer board group).

International, multicenter, observational, longitudinal monitoring study to identify biomarker/s for Friedreich's Ataxia and to explore the clinical robustness, specificity, and long-term variability of these biomarker/s

This is a multi-site, observational study to evaluate the long-term safety and efficacy of CTX001 in subjects who received CTX001 in Study CTX001-111 (NCT03655678) or VX21-CTX001-141 (transfusion-dependent β-thalassemia [TDT] studies) or Study CTX001-121 (NCT03745287) or VX21-CTX001-151 (severe sickle cell disease [SCD] studies; NCT05329649).

SLC13A5 deficiency (Citrate Transporter Disorder, EIEE 25) is a rare genetic disorder with neurodevelopmental delays and seizure onset in the first few days of life. This natural history study is designed to address the lack of understanding of disease progression and genotype-phenotype correlation. Additionally it will help in identifying clinical endpoints for use in future clinical trials.

The purpose of this research study is to identify individuals that have a rare genetic disease without an adequate therapeutic strategy that might be treatable with drug developed to target the disease-causing genetic alteration.

The project is focused on the detailed study of structural genomic variants (SVs). Such genetic mutations are in fact alterations in the DNA molecule structure and include copy number variants, inversions and translocations. A single event may affect many genes as well as regulatory regions and the specific phenotypic consequences will depend on the location, genetic content and type of SV. Many times, the specific disease-causing mechanism is not known. Here, we plan to study the molecular genetic behavior of structural variants as well as the underlying mutational mechanisms involved. First, we will use genome sequencing to pinpoint the chromosomal breakpoints at the nucleotide level, characterize the genomic architecture at the breakpoints and study the relationship between structural variants and SNVs. Second, we will study how structural variants impact gene expression. Finally, we will functionally explore the disease mechanisms in vivo using zebrafish and in vitro using primary patient cells and induced pluripotent stem cells. Our studies will focus on the origin, structure and impact of structural variation on human disease. The results will directly lead to a higher mutation detection rate in genetic diagnostics. Through a better understanding of disease mechanisms our findings will also assist in the development of novel biomarkers and therapeutic strategies for patients with rare genetic disorders.

Parkinson's disease (PD) is the second most common neurodegenerative disease, which affects 2-3% of the general population above 65 years. There are significant differences in incidence depending on geographical location, race, and ethnicity. The exact cause of the disease is still unknown, but the role of genetic and environmental factors has already been established. Certain genetic forms of the disease make up for a small percentage, so it is thought that environmental factors have a more significant impact on the development of the disease. The incidence of PD is higher in people exposed to significant quantities of pesticides and traumatic brain injury, while there is a smaller incidence in smokers and people consuming more significant quantities of caffeine. The project will finish in four years, with the first 20 months dedicated to the first phase (genetic-epidemiological research), and the entirety of the 48 months for the second phase of the project (prospective clinical research). The main goal of the first phase of the project is to determine which genetic mutations are the ones most represented in the Croatian population afflicted with the familial form of PD. In the second phase the main goal is to determine the influence of genetic factors and microbiological factors on the disease's progression as well as on the treatment outcomes. Specific goals of this part of the project are to determine how many patients in the general population of PD patients present with a genetic disorder and which genes have a role in that disorder, as well as determine the composition of intestinal and oral microbiota both in the patient test group and the healthy control group. Furthermore, specific goals are to evaluate the effects of standard PD treatment on the composition of microbiota, neurodegeneration progression and the activity of neuroinflammation in the central nervous system (CNS) and to examine whether there is a link between the physiological and the pathophysiological function of microbiota, using markers of disease progression and glial activity. Last specific goal is to analyze potential pathological conformation protein forms that could be used as a biomarker in early stages of the disease and a biomarker of disease progression. The first phase of the study will provide the first epidemiologic data on the familial form of PD, as well as the mutations most represented in patients with PD in Croatia. Additionally, the prospective clinical study will contribute to enlightening the intertwined effects of genetic and environmental factors in the emergence and progression of the disease, as well as their effect on treatment outcome. Intestinal and oral microbiota composition analysis will determine whether there is a difference between PD and the healthy population while using the short-chain fatty acid profile will determine the metabolic differences between the two groups. Analyzing the markers of CNS homeostasis, inflammation, and neuroglial function will determine the progression of the disease and also correlate them to genetic factors as well as the microbiota function and composition. Analyzing the pathological conformation forms of alpha-synuclein could lead to the discovery of novel biomarkers in the early stages of the disease, as well as to follow the progression of the disease

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....

In this study, we will conduct retrospective chart and imaging reviews and prospective longitudinal virtual assessments of individuals with LBSL.

The researchers hope to establish an overall program of early genetic screening for neonatal critical illness in China, and to develop precise intervention strategies to assist clinical diagnosis and treatment of hereditary critical illness.