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The purpose of this study is to provide advanced genetic testing and virtual consultations for seriously ill newborns in hospitals in Texas with fewer resources, especially along the Texas-Mexico border. The researchers also want to know how well the virtual consultation tool, called Consultagene, works in these hospitals by gathering feedback from healthcare providers. Researchers will provide rapid whole genome sequencing (WGS) to 200 infants over a period of 5 years. Data will be collected via Consultagene, surveys, and qualitative interviews.
Each year world-wide, 2.5 million fetuses die unexpectedly in the last half of pregnancy, 25,000 in the United States, making fetal demise ten-times more common than Sudden Infant Death Syndrome. This study will apply a novel type of non-invasive monitoring, called fetal magnetocardiography (fMCG) used thus far to successfully evaluate fetal arrhythmias, in order to discover potential hidden electrophysiologic abnormalities that could lead to fetal demise in five high-risk pregnancy conditions associated with fetal demise.
The investigators propose a preliminary study performing exome sequencing on samples from patients and their biologically related family members with tracheal and esophageal birth defects (TED). The purpose of this study is to determine if patients diagnosed with TED and similar disorders carry distinct mutations that lead to predisposition. The investigators will use advanced, non-invasive magnetic resonance imaging (MRI) techniques to assess tracheal esophageal, lung, and cardiac morphology and function in Neonatal Intensive Care Unit (NICU) patients. MRI techniques is done exclusively if patient is clinically treated at primary study location and if patient has not yet had their initial esophageal repair.
Prematurely born children are at higher risk of cognitive impairments and behavioral disorders than full-term children. There is growing evidence of significant volumetric and shape abnormalities in subcortical structures of premature neonates, which may be associated to negative long-term neurodevelopmental outcomes. The general objective is to look directly at the long-term neurodevelopmental implications of these neonatal subcortical structures abnormalities. Investigators propose to develop biomarkers of prematurity by comparing the morphological and diffusion properties of subcortical structures between preterm, with and without associated brain injuries, and full-term neonates using brain MRI. By combining subcortical morphological and diffusion properties, investigators hypothesize to be able to: (1) delineate specific correlative relationships between structures regionally and differentially affected by normal maturation and different patterns of white matter injury, and (2) improve the specificity of neuroimaging to predict neurodevelopmental outcomes earlier. The specific aims and general methodology are: 1) Build a new toolbox for neonatal subcortical structures analyses that combine a group lasso-based analysis of significant regions of shape changes, a structural correlation network analysis, a neonatal tractography, and tensor-based analysis on tracts; 2) Ascertain biomarkers of prematurity in neonates with different patterns of abnormalities using correlational and connectivity analysis within and between structures features; 3) Assess the predictive potential of subcortical imaging on neurodevelopmental outcomes by correlating neonatal imaging results with long-term neurodevelopmental scores at 9 and 18 months, and 6-8 years, follow-up. In each of these aims, investigators will use advanced neuroimaging analysis developed by their group and collaborator, including multivariate tensor-based morphometry and multivariate tract-based analysis. This application will provide the first complete subcortical network analysis in both term and preterm neonates. In the first study of its kind for prematurity, investigators will use sparse and multi-task learning to determine which of the biomarkers of prematurity at birth are the best predictors of long-term outcome. Once implemented, these methods will be available to compare subcortical structures for other pathologies in newborns and children.
Background: Some head and facial abnormalities are rare and present at birth. Others are more common, and may not show up until puberty. These conditions have different causes and characteristics. Researchers want to learn more about these conditions by comparing people with face, head, and neck abnormalities to family members and to healthy volunteers without such conditions. Objectives: To learn more about abnormal development of the face, head, and neck. To determine their genetic variants. Eligibility: People who have not had surgery for facial trauma: People ages 2 and older with craniofacial abnormalities (may participate offsite) Unaffected relatives ages 2 and older Healthy volunteers ages 6 and older Design: Participants will be screened with medical history and physical exam focusing on head, face, and neck Participants may be followed for several years. Visits may require staying near the clinic for a few days. A visit is required for the following developmental stages, along with follow-up visits: Age 2-6 Age 6-10 Age 11-17 Age 18 and older Visits may include: Medical history Physical exam Questionnaires Oral exam Blood and urine tests Cheek swab: a cotton swab will be wiped across the inside of the cheek several times. Cone beam CT scan (CBCT): x-rays create an image of the head, face, teeth, and neck. Participants will stand still or sit on a chair for about 20 minutes while the scanner rotates around the head. Photos of the head and face Offsite participants will provide: Copies of medical and dental records Leftover tissue samples from previous surgery Blood sample or cheek swab
Kidney stones continue to affect more and more people in the United States with the most recent estimate being 1 in 9 people will develop a stone in their life. While family history is a known risk factor for stone disease, it remains unclear whether this is related to learned dietary habits or a truly inheritable genetic condition. Known inheritable genetic conditions linked to stone formation are uncommon, and thus, routine genetic testing is not currently recommended by any major urologic organizations. Patients who form calcium phosphate predominant stones, a less common type of stone composition, tend to have alkaline urine pH which suggests that the kidneys are unable to rid the body of acid. Management of such patients for stone prevention can be difficult. The Iowa Institute for Human Genomics is one of only a handful of commercial labs which offers genetic testing for stone disease. The aim of this study is to assess the rate of genetic abnormalities amongst calcium phosphate predominant stone formers with alkaline urine. To this end, the investigators plan to enroll calcium phosphate predominant stone forming patients with alkaline urine on 24 hour urine collection who obtain their health care at UIHC to undergo free genetic testing via blood draw to assess for genetic abnormalities. The investigators will also collect information already available in the subject's chart to assess for other patterns between blood and urine tests and any genetic variants.
There is no consensus regarding the neurological substrate underpinning ASD. The investigators describe the novel concept of "social reciprocity network" and hypothesize that aberrant connectivity/oscillatory patterns affecting this network contribute to the core deficits in ASD. The overarching goal of this trial is to explore abnormalities involving the neuronal connectivity and oscillatory patterns within the social reciprocity network and to elucidate the role of modulating this network via rTMS in improving the above measures and social cognition in ASD. Quantitative electroencephalography (QEEG) coherence and spectral power analysis are reliable measures of neuronal connectivity and dynamics. The investigators aim to study the QEEG coherence/spectral power analysis to explore the neuronal dynamics affecting the social reciprocity network in ASD.
Background: Ollier disease (OD) and Maffucci syndrome (MS) are rare disorders that increase the risk of cancers in cartilage tissue. These tumors can lead to severe skeletal deformities beginning in childhood. People with OD or MS are also at an increased risk of blood vessel disorders and specific cancers. Researchers want to learn more about what causes these disorders. Objective: To understand the genetic causes of OD and MS. Eligibility: People aged 2 years and older who have OD or MS with cartilage tumors or blood vessel disorders. Design: Participants will stay at the NIH clinic for 5 days. They will undergo these procedures: A physical exam with blood tests. DXA (dual-energy X-ray absorptiometry) scan. The DXA scan measures the density of bones. Participants will lie on a table while a machine uses low-level X-rays to scan their body. MRI (magnetic resonance imaging) scan. An MRI uses strong magnets to take pictures of the tissues inside the body. Participants will lie on a table that slides into a large tube. A contrast dye may be injected through a needle inserted into a vein in the arm. X-rays. Some participants may have full-body X-rays instead of an MRI. X-rays take pictures of bones and other internal tissues and organs, such as the heart, lungs, and airways. PET (positron emission tomography) and CT (computed tomography) scans. Adult participants will have 2 other scans. The PET scan will include a radioactive injection into a vein. They will also have a full-body CT scan.
The purpose of this study is to compare changes in RV structure and function, biomarkers, and patient reported outcomes between TOF patients randomized to an ARNI vs placebo.
The "Gonadal Dysgenesis Tissue Cryopreservation for Fertility Preservation" study is open to a subset of patients with disorders of sex development (DSD) which is associated with the risk of malignancy and a high risk of infertility or sterility. For these patients, experimental gonadal tissue cryopreservation is the only fertility preservation option available. The overall objective of this study is to determine the safety and efficacy of gonadal tissue cryopreservation as a method of preserving fertility and/or restoring hormonal function in patients with gonadal dysgenesis who are at risk of decreased fertility potential or malignancy.