Abstract

Technological developments in the field of genomics now afford the opportunity to define the complete sequence of an individual's genome in a rapid and affordable manner. Such """"""""whole genome sequencing"""""""" and its simpler corollary, """"""""whole exome sequencing"""""""" (WES), have already established themselves as powerful research tools. The natural next step in the evolution of this technology is its direct application in the clinical arena. However, while such technology holds considerable clinical promise, tremendous challenges exist in applying it and deriving practical benefit to patients. In this proposal we outline a highly interdisciplinary approach to identifying, confronting and overcoming the major challenges which must be met in order to implement deep sequencing technology in clinical medicine.
Aim 1 will explore the use of WES as a diagnostic tool in the care of a broad array of patients, evaluate its performance, identify critical clinical characteristics which can guide its application and measure the impact of such information on patients and providers.
Aim 2 will tackle one of the most pressing challenges in the clinical application of WES: the inevitable generation of """"""""collateral"""""""" or """"""""bystander"""""""" information. Educational materials will be developed to enable patients to make decisions about appropriate return of results and the impact of collateral information will be assessed at the level of the provider, laboratory and patient. The third major challenge in clinical implementation of genomic medicine, how do deal with vast amounts of information, will be addressed by Aim 3. A clinically oriented """"""""binning"""""""" structure will be created and refined for classifying, storing and transmitting data within practical categories so as to make sense of the large amounts of data generated. Finally, as we stand on the cusp of genomic medicine, we must ensure that all have access to its benefits. Thus, Aim 4 will pursue clinical WES in traditionally underrepresented populations to identify special opportunities and challenges in the clinical translation of this new tool to the broadest possible population. Our ultimate aim is to establish a set of best practices to guide future implementation of robust genomic technologies for the real and practical betterment of human health.

Public Health Relevance

Genomic medicine has tremendous potential to improve human health by facilitating improved diagnosis, offering deep insight into mechanisms of disease and by enabling individually targeted prevention and treatment. In this proposal we will confront the major challenges which stand between genomic medicine and its broad implementation to a diverse population.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Human Genome Research Institute (NHGRI)
Type
Research Project--Cooperative Agreements (U01)
Project #
5U01HG006487-03
Application #
8582067
Study Section
Special Emphasis Panel (ZHG1-HGR-N (O1))
Program Officer
Hindorff, Lucia
Project Start
2011-12-05
Project End
2015-11-30
Budget Start
2013-12-01
Budget End
2014-11-30
Support Year
3
Fiscal Year
2014
Total Cost
$1,684,490
Indirect Cost
$538,281

  Institution

Name
University of North Carolina Chapel Hill
Department
Genetics
Type
Schools of Medicine
DUNS #
608195277
City
Chapel Hill
State
NC
Country
United States
Zip Code
27599

  Publications

Roche, Myra I; Griesemer, Ida; Khan, Cynthia M et al. (2018) Factors influencing NCGENES research participants' requests for non-medically actionable secondary findings. Genet Med :
Porter, Kathryn M; Kauffman, Tia L; Koenig, Barbara A et al. (2018) Approaches to carrier testing and results disclosure in translational genomics research: The clinical sequencing exploratory research consortium experience. Mol Genet Genomic Med 6:898-909
Rini, Christine; Khan, Cynthia M; Moore, Elizabeth et al. (2018) The who, what, and why of research participants' intentions to request a broad range of secondary findings in a diagnostic genomic sequencing study. Genet Med 20:760-769
Wolf, Susan M; Amendola, Laura M; Berg, Jonathan S et al. (2018) Navigating the research-clinical interface in genomic medicine: analysis from the CSER Consortium. Genet Med 20:545-553
Skinner, Debra; Roche, Myra I; Weck, Karen E et al. (2018) ""Possibly positive or certainly uncertain?"": participants' responses to uncertain diagnostic results from exome sequencing. Genet Med 20:313-319
Ormond, Kelly E; Hallquist, Miranda L G; Buchanan, Adam H et al. (2018) Developing a conceptual, reproducible, rubric-based approach to consent and result disclosure for genetic testing by clinicians with minimal genetics background. Genet Med :
Strande, Natasha T; Brnich, Sarah E; Roman, Tamara S et al. (2018) Navigating the nuances of clinical sequence variant interpretation in Mendelian disease. Genet Med 20:918-926
Hart, M Ragan; Biesecker, Barbara B; Blout, Carrie L et al. (2018) Secondary findings from clinical genomic sequencing: prevalence, patient perspectives, family history assessment, and health-care costs from a multisite study. Genet Med :
Amendola, Laura M; Berg, Jonathan S; Horowitz, Carol R et al. (2018) The Clinical Sequencing Evidence-Generating Research Consortium: Integrating Genomic Sequencing in Diverse and Medically Underserved Populations. Am J Hum Genet 103:319-327
Sanghvi, Rashesh V; Buhay, Christian J; Powell, Bradford C et al. (2018) Characterizing reduced coverage regions through comparison of exome and genome sequencing data across 10 centers. Genet Med 20:855-866

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