Your search keyword '"Carey, David J."' showing total 4 results

1. Correction to: Systematic characterization of germline variants from the DiscovEHR study endometrial carcinoma population

Author

Miller, Jason E., Metpally, Raghu P., Person, Thomas N., Krishnamurthy, Sarathbabu, Dasari, Venkata Ramesh, Shivakumar, Manu, Lavage, Daniel R., Cook, Adam M., Carey, David J., Ritchie, Marylyn D., Kim, Dokyoon, Gogoi, Radhika, and on behalf of the DiscovEHR collaboration

Published

2019

2. MicroRNA expression signature in human abdominal aortic aneurysms

Author

Pahl Matthew C, Derr Kimberly, Gäbel Gabor, Hinterseher Irene, Elmore James R, Schworer Charles M, Peeler Thomas C, Franklin David P, Gray John L, Carey David J, Tromp Gerard, and Kuivaniemi Helena

Subjects

Apoptosis, Microarray analysis, Vascular biology, miRNA-mRNA analysis, Network analysis, Internal medicine, RC31-1245, Genetics, QH426-470

Abstract

Abstract Background Abdominal aortic aneurysm (AAA) is a dilatation of the aorta affecting most frequently elderly men. Histologically AAAs are characterized by inflammation, vascular smooth muscle cell apoptosis, and extracellular matrix degradation. The mechanisms of AAA formation, progression, and rupture are currently poorly understood. A previous mRNA expression study revealed a large number of differentially expressed genes between AAA and non-aneurysmal control aortas. MicroRNAs (miRNAs), small non-coding RNAs that are post-transcriptional regulators of gene expression, could provide a mechanism for the differential expression of genes in AAA. Methods To determine differences in miRNA levels between AAA (n = 5) and control (n = 5) infrarenal aortic tissues, a microarray study was carried out. Results were adjusted using Benjamini-Hochberg correction (adjusted p Results A microarray study identified eight miRNAs with significantly different expression levels between AAA and controls (adjusted p Conclusions Our genome-wide approach revealed several differentially expressed miRNAs in human AAA tissue suggesting that miRNAs play a role in AAA pathogenesis.

Published

2012

3. Systematic characterization of germline variants from the DiscovEHR study endometrial carcinoma population.

Author

Miller, Jason E., Metpally, Raghu P., Person, Thomas N., Krishnamurthy, Sarathbabu, Dasari, Venkata Ramesh, Shivakumar, Manu, Lavage, Daniel R., Cook, Adam M., Carey, David J., Ritchie, Marylyn D., Kim, Dokyoon, and Gogoi, Radhika

Subjects

ELECTRONIC health records, ENDOMETRIAL cancer, CARCINOMA, HOSPITALS, CANCER in women

Abstract

Background: Endometrial cancer (EMCA) is the fifth most common cancer among women in the world. Identification of potentially pathogenic germline variants from individuals with EMCA will help characterize genetic features that underlie the disease and potentially predispose individuals to its pathogenesis. Methods: The Geisinger Health System's (GHS) DiscovEHR cohort includes exome sequencing on over 50,000 consenting patients, 297 of whom have evidence of an EMCA diagnosis in their electronic health record. Here, rare variants were annotated as potentially pathogenic. Results: Eight genes were identified as having increased burden in the EMCA cohort relative to the non-cancer control cohort. None of the eight genes had an increased burden in the other hormone related cancer cohort from GHS, suggesting they can help characterize the underlying genetic variation that gives rise to EMCA. Comparing GHS to the cancer genome atlas (TCGA) EMCA germline data illustrated 34 genes with potentially pathogenic variation and eight unique potentially pathogenic variants that were present in both studies. Thus, similar germline variation among genes can be observed in unique EMCA cohorts and could help prioritize genes to investigate for future work. Conclusion: In summary, this systematic characterization of potentially pathogenic germline variants describes the genetic underpinnings of EMCA through the use of data from a single hospital system. [ABSTRACT FROM AUTHOR]

Published

2019

4. The IGNITE network: a model for genomic medicine implementation and research.

Author

Weitzel KW, Alexander M, Bernhardt BA, Calman N, Carey DJ, Cavallari LH, Field JR, Hauser D, Junkins HA, Levin PA, Levy K, Madden EB, Manolio TA, Odgis J, Orlando LA, Pyeritz R, Wu RR, Shuldiner AR, Bottinger EP, Denny JC, Dexter PR, Flockhart DA, Horowitz CR, Johnson JA, Kimmel SE, Levy MA, Pollin TI, and Ginsburg GS

Subjects

Cooperative Behavior, Genetic Testing, Geography, Humans, Precision Medicine, Biomedical Research, Genomics, Models, Theoretical

Abstract

Background: Patients, clinicians, researchers and payers are seeking to understand the value of using genomic information (as reflected by genotyping, sequencing, family history or other data) to inform clinical decision-making. However, challenges exist to widespread clinical implementation of genomic medicine, a prerequisite for developing evidence of its real-world utility., Methods: To address these challenges, the National Institutes of Health-funded IGNITE (Implementing GeNomics In pracTicE; www.ignite-genomics.org ) Network, comprised of six projects and a coordinating center, was established in 2013 to support the development, investigation and dissemination of genomic medicine practice models that seamlessly integrate genomic data into the electronic health record and that deploy tools for point of care decision making. IGNITE site projects are aligned in their purpose of testing these models, but individual projects vary in scope and design, including exploring genetic markers for disease risk prediction and prevention, developing tools for using family history data, incorporating pharmacogenomic data into clinical care, refining disease diagnosis using sequence-based mutation discovery, and creating novel educational approaches., Results: This paper describes the IGNITE Network and member projects, including network structure, collaborative initiatives, clinical decision support strategies, methods for return of genomic test results, and educational initiatives for patients and providers. Clinical and outcomes data from individual sites and network-wide projects are anticipated to begin being published over the next few years., Conclusions: The IGNITE Network is an innovative series of projects and pilot demonstrations aiming to enhance translation of validated actionable genomic information into clinical settings and develop and use measures of outcome in response to genome-based clinical interventions using a pragmatic framework to provide early data and proofs of concept on the utility of these interventions. Through these efforts and collaboration with other stakeholders, IGNITE is poised to have a significant impact on the acceleration of genomic information into medical practice.

Published

2016