Noninvasive prenatal genetic testing, which utilizes cell-free fetal DNA and advances in sequencing technology, is revolutionizing the practice of obstetrics. While currently used as a screen for a limited number of aneuploidies and genetic conditions, noninvasive testing is anticipated to employ whole fetal exome and genome sequencing to identify not only monogenic disorders but also microduplications, microdeletions, and variants of uncertain clinical significance.

Prenatal testing is evolving in two important ways: first, advances in genomic medicine mean that samples of fetal DNA obtained with invasive methods (such as amniocentesis) can be analyzed using microarray analysis or whole genome sequencing, revealing far more information about the fetus's genetic make-up than was previously possible; and second, new, non-invasive prenatal tests have been introduced that isolate fragments of fetal DNA circulating in a pregnant woman's blood, making possible safe, highly accurate genetic testing much earlier in pregnancy than was previously possi

Interactive Multimedia Consent for Biobanking Abstract Many biobanks in the U.S. consent thousands of contributors of biospecimens and health information. There is growing interest in the efficiency of electronic consenting (e-consent) given the scale of these efforts. However, e-consent tools also need to promote diverse users' understanding and trust, and demonstrate their effectiveness in comparison to traditional methods such as face-to-face (F2F) consenting.

Advances in psychiatric genetics are likely to offer major diagnostic and therapeutic benefits, but also legal and social-related risks, to individuals who were diagnosed with, or have a proclivity for, psychiatric disorders. In response, courts and policy-makers will have to ensure that psychiatric genetic data are used to promote, and not to obstruct, equality, justice, and social inclusion.

This project employs multiple methods and a transdisciplinary approach to explore policy options for US federal and state governments seeking to address how life, long-term care, and disability insurers use genetic information. The analysis will focus on legal standards of actuarial justification, that is, the requirement that insurers m+R409ust show a statistical correlation between a risk factor and increased cost in order to use that factor in an underwriting decision such as a policy denial or an increased premium.

Targeted gene sequencing using large panels has become an increasingly important strategy for evaluating disease risk for many inherited diseases. Expanded gene panels are more sensitive than single gene testing and often more cost effective than sequential testing, leading to additional diagnostic and prevention opportunities. However, these panels also identify rare variants of uncertain clinical significance (VUS) in many patients.

Genomic literacy plays a critical role in informed decision-making for genomic testing, in the implementation of the test and the accurate interpretation of the results, and in our policy making process as a society. The National Human Genome Research Institute's 2011 vision for the future of genomic medicine specifically cites the need for both providers and consumers to achieve genomic literacy. Yet despite its importance, there is no effective tool for assessing genomic literacy.

Precision medicine is an emerging approach for disease treatment and prevention that takes into account individual variability in genes, environment, and lifestyle for each person. The Precision Medicine Initiative (PMI) was recently launched by the NIH to accelerate the pace of discovery. Though initially focused on cancer, the PMI will eventually generate knowledge applicable to a range of diseases, including infectious diseases.

This application is to fund the University of Utah Center of Excellence in ELSI Research (UCEER). The University of Utah has a strong tradition in human genetics and ELSI research and this proposal will build on our successful development and management of a P20 funded CEER. The proposed UCEER will focus primarily, although not exclusively, on issues relevant to population screening for genetic conditions in the healthcare of women, children, and young families.

This 3-year R01 based at the University of Minnesota and Vanderbilt University will convene a national Working Group of top legal and scientific experts to analyze current U.S. federal and state law, regulation, and guidance on translational genomics, and to generate consensus recommendations on what the law should be, to optimize successful translation of genomics into clinical use. The law underlying genomics is currently unclear, poorly understood, and contested.