View clinical trials related to Genetic Diseases, Inborn.
Filter by:LIPIGEN is an observational study involving Italian physicians and researchers in the field of diseases related to blood lipid levels. This study aims to improve the diagnosis and treatment of people with familial dyslipidaemias, including very common conditions such as familial hypercholesterolaemia (FH) and less common ones such as familial chylomicronidaemic syndrome (FCS). What does the study do? It collects information on Italian patients with Familial Hypercholesterolaemia (FH), following them in their normal clinical examination without adding extra procedures. It uses the data collected to further our understanding of diseases such as familial hypercholesterolaemia, examining how it is diagnosed clinically and by genetic testing, and evaluating the effectiveness of different treatments. It seeks to identify the genetic mutations that cause familial hypercholesterolaemia and other dyslipidaemias, helping to choose the most effective treatments. It evaluates the impact of long-term treatments and patient adherence to medication, as well as monitoring the incidence of cardiovascular events and other important outcomes. Who can participate? The study is aimed at people of all ages, from children to adults, with familial hypercholesterolaemia or other genetic dyslipidaemia. More than 50 centres throughout Italy are involved, making the study accessible to many. What does participation entail? Participants will continue with their normal clinical practice. Data such as family history, personal clinical findings and genetic information will be collected, without additional procedures. For some, further evaluations, such as ultrasounds, may be required to better study their condition. The LIPIGEN study not only helps to better understand diseases related to high cholesterol but also aims to improve patients' lives through more precise diagnosis and personalised treatments.
Pancreatic cancer is one of the diseases with the worst prognosis, which is mainly due to the initial asymptomatic prognosis. Unfortunately, the incidence of this disease in the Czech Republic is still increasing. In a certain proportion of patients, it is possible to predict the disease, e.g. due to family burdens. Regular follow-up of such individuals is the subject of the SCREPAN study: "Pancreatic Cancer Screening in High-Risk Persons".
The goal of this clinical trial is to test a new method for newborn screening using whole genome sequencing, called BeginNGS. Parents will be approached to provide informed consent to enroll their newborns in prenatal, postnatal, and outpatient settings. The main questions this study aims to answer are: What is the utility of BeginNGS as compared to state newborn screening? What is the acceptability and feasibility of BeginNGS as compared to state newborn screening? What is the cost effectiveness of BeginNGS as compared to state newborn screening? Enrolled newborns will have a blood sample taken and will receive the BeginNGS test. Newborns will have also had the state newborn screening test.
Transcranial magnetic stimulation (TMS) uses electromagnetic induction as an efficient, painless, non-invasive method to generate a suprathreshold current at the level of the encephalon, and provide in vivo measurements of cortical excitability and reactivity at the level of the motor cortex (TMS-EMG) or the entire cortical mantle (TMS-EEG). This study proposes TMS measurements as a diagnostic tool in patients to understand mechanisms of epileptogenesis related to genetic mutations, and prognostic to guide and monitor precision treatments.
Over the past twenty years, Prof. Yanick Crow and his team have developed internationally recognized expertise in genetic pathologies affecting the immune and neurological systems. The pathologies studied have a particularly severe impact on patients' quality of life, with a high mortality rate and a significant risk of occurrence in affected families. These pathologies are rare, and very often under-diagnosed. To date, there is virtually no effective curative treatment. Prof. Crow's team operates at the frontier between clinical and research work, and from experience, the team knows that patients and families affected by these serious pathologies are often highly motivated to help research into the pathology that affects them. Initially, Prof. Crow's research focused primarily on the study of the genetic disease Aicardi-Goutières Syndrome (AGS). However, there is an undeniable clinical and pathological overlap between AGS and other forms of disease such as autoimmune systemic lupus erythematosus and many other genetic pathologies - e.g. familial lupus engelure, spondyloenchondromatosis and COPA syndrome. This is why research is being extended to all genetic diseases with immune and neurological dysfunctions.
object name: Multicenter analysis of genomic and metabolic data of neonatal genetic diseases. goal of study:(1) Gene sequencing data (138 genes related to 133 common genetic diseases) and tandem mass spectrometry metabolomics data (11 amino acids and 28 acylcarnitines) of about 40,000 newborns from the South China Neonatal Genetic Screening Alliance participating units were collected and collated to complete the database construction of genes and mass spectrometry. (2) Explore the use of genome and metabolome big data and machine learning algorithms such as Random forest, Support Vector Machine, Elastic net, Multilayer Perceptron to construct prediction models for common genetic diseases, and strive to achieve accurate diagnosis and prediction of common genetic diseases using simple tandem mass spectrometry metabolome data, and expand the application range of tandem mass spectrometry technology for disease detection. research design:retrospective observational study Research period:September 2022 to December 2025 Participating units:South China Neonatal genetic screening Alliance (including cooperation units of 123 hospitals) research object:Gene screening data of 40,000 newborns ( 138 genes related to 133 common genetic diseases ) and tandem mass spectrometry data ( 11 amino acids and 28 acylcarnitines ). Inclusion criteria:( 1 ) Newborns who underwent genetic screening and tandem mass spectrometry at the same time. ( 2 ) Age : 0-28 days, gestational age 37-42 weeks. Excluded criteria:Data that meets any of the following conditions need to be eliminated : ( 1 ) Neonatal data with unclear clinical basic information ; ( 2 ) Lack of traceability core information data ; ( 3 ) The data that the test results cannot be analyzed and interpreted. data collection:( 1 ) Basic information : gender, age, sample type, subject traceability number / ID number, etc. ( 2 ) Clinical symptoms, biochemical and imaging data of positive samples. ( 3 ) Gene detection results and tandem mass spectrometry results. ( 4 ) Date of test data, instrument model, reagent type, etc.
The aim of the current project is to evaluate the penetrance of elevated plasma Lp(a) levels in patients with atherosclerotic coronary artery disease to their first- and second-degree biological relatives based on data from a clinical health care development project.
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. Additionally it will identify clinical and biomarker endpoints for use in future clinical trials.
The purpose of this study is to evaluate the safety and efficacy of RM-004 for Hemoglobin H-Constant Spring disease.
Genomic methods can significantly contribute to all facets of precision medicine, from diagnosis to prevention, therapeutic intervention, and management of acute and chronic illnesses. DNA based methods are already having a considerable impact across healthcare in fields that include: public health, infectious disease monitoring, acute and chronic disease, pharmacogenomics, prenatal testing and diagnosis, and therapeutic development. In this proposal, investigators are focusing on the application of genomic methods in precision medicine - specifically on rapid whole-genome sequencing of parents and children (i.e. a trio) for the identification of diseases that have genetic components. Goals Primary goal: is to provide safe rapid whole genome sequencing to Neonatal Intensive Care Unit/Pediatric Intensive Care Unit patients. Secondary goals: 1) Although several groups globally are implementing rapid sequencing of rare disease, these are predominantly in the research space, with many unanswered questions regarding the best way to implement them into a national healthcare system. Each country and their healthcare systems are unique, and valuable knowledge will be gained by implementing this process within a New Zealand context. As part of this the study will measure the impact on the individuals and families. 2) to expand the research team's understanding of non-coding disease-causing variants and methylation changes that contribute to severe disease in early life. Primary Aims 1. To incorporate long-read RNA sequencing data into the diagnostic rapid Whole Genome Sequencing pipeline to provide a direct measure of the functional outcome of the variants of clinical concern. 2. To measure the clinical utility of analysing non-coding variants in the diagnosis of critically ill children who do not have pathogenic, likely pathogenic, or variants of unknown significance for mendelian disorders. 3. To identify, in a real-world setting within the New Zealand health-care system, the clinical and economic effects of deploying rapid Whole Genome Sequencing-informed rapid precision medicine for critically ill children.