Your search keyword '"Karnovsky, Alla"' showing total 4 results

1. Sparse network modeling and metscape-based visualization methods for the analysis of large-scale metabolomics data.

Author

Basu, Sumanta, Duren, William, Evans, Charles R., Burant, Charles F., Michailidis, George, and Karnovsky, Alla

Subjects

SYSTEMS biology, SCIENTIFIC visualization, METABOLOMICS, MASS spectrometry, METABOLIC profile tests, BIOINFORMATICS, COMPUTERS in biology

Abstract

Motivation: Recent technological advances in mass spectrometry, development of richer mass spectral libraries and data processing tools have enabled large scale metabolic profiling. Biological interpretation of metabolomics studies heavily relies on knowledge-based tools that contain information about metabolic pathways. Incomplete coverage of different areas of metabolism and lack of information about non-canonical connections between metabolites limits the scope of applications of such tools. Furthermore, the presence of a large number of unknown features, which cannot be readily identified, but nonetheless can represent bona fide compounds, also considerably complicates biological interpretation of the data. Results: Leveraging recent developments in the statistical analysis of high-dimensional data, we developed a new Debiased Sparse Partial Correlation algorithm (DSPC) for estimating partial correlation networks and implemented it as a Java-based CorrelationCalculator program. We also introduce a new version of our previously developed tool Metscape that enables building and visualization of correlation networks. We demonstrate the utility of these tools by constructing biologically relevant networks and in aiding identification of unknown compounds. [ABSTRACT FROM AUTHOR]

Published

2017

2. Metscape 2 bioinformatics tool for the analysis and visualization of metabolomics and gene expression data.

Author

Karnovsky, Alla, Weymouth, Terry, Hull, Tim, Tarcea, V. Glenn, Scardoni, Giovanni, Laudanna, Carlo, Sartor, Maureen A., Stringer, Kathleen A., Jagadish, H. V., Burant, Charles, Athey, Brian, and Omenn, Gilbert S.

Subjects

*METABOLITE analysis, *BIOINFORMATICS, *GENE expression, *MOLECULAR biology, *CELLULAR signal transduction, *DATABASES

Abstract

Motivation: Metabolomics is a rapidly evolving field that holds promise to provide insights into genotype–phenotype relationships in cancers, diabetes and other complex diseases. One of the major informatics challenges is providing tools that link metabolite data with other types of high-throughput molecular data (e.g. transcriptomics, proteomics), and incorporate prior knowledge of pathways and molecular interactions.Results: We describe a new, substantially redesigned version of our tool Metscape that allows users to enter experimental data for metabolites, genes and pathways and display them in the context of relevant metabolic networks. Metscape 2 uses an internal relational database that integrates data from KEGG and EHMN databases. The new version of the tool allows users to identify enriched pathways from expression profiling data, build and analyze the networks of genes and metabolites, and visualize changes in the gene/metabolite data. We demonstrate the applications of Metscape to annotate molecular pathways for human and mouse metabolites implicated in the pathogenesis of sepsis-induced acute lung injury, for the analysis of gene expression and metabolite data from pancreatic ductal adenocarcinoma, and for identification of the candidate metabolites involved in cancer and inflammation.Availability: Metscape is part of the National Institutes of Health-supported National Center for Integrative Biomedical Informatics (NCIBI) suite of tools, freely available at http://metscape.ncibi.org. It can be downloaded from http://cytoscape.org or installed via Cytoscape plugin manager.Contact: metscape-help@umich.edu; akarnovs@umich.eduSupplementary information: Supplementary data are available at Bioinformatics online. [ABSTRACT FROM PUBLISHER]

Published

2012

3. Metabolic consequences of sepsis-induced acute lung injury revealed by plasma 1H-nuclear magnetic resonance quantitative metabolornics and computational analysis.

Author

Stringer, Kathleen A., Serkova, Natalie J., Karnovsky, Alla, Guire, Kenneth, Paine III, Robert, and Standiford, Theodore J.

Subjects

SEPSIS, LUNG injuries, NUCLEAR magnetic resonance spectroscopy, SYSTEMS biology, METABOLITES, DRUG therapy

Abstract

Metabolomics is an emerging component of systems biology that may be a viable strategy for the identification and validation of physiologically relevant biomarkers. Nuclear magnetic resonance (NMR) spectroscopy allows for establishing quantitative data sets for multiple endogenous metabolites without preconception. Sepsis-induced acute lung injury (ALI) is a complex and serious illness associated with high morbidity and mortality for which there is presently no effective pharmacotherapy. The goal of this study was to apply 1H-NMR based quantitative metabolomics with subsequent computational analysis to begin working towards elucidating the plasma metabolic changes associated with sepsis-induced ALI. To this end, this pilot study generated quantitative data sets that revealed differences between patients with ALI and healthy subjects in the level of the following metabolites: total glutathione, adenosine, phosphatidylserine, and sphingomyelin. Moreover, myoinositol levels were associated with acute physiology scores (APS) (ρ = -0.53, P = 0.05, q = 0.25) and ventilator-free days (ρ? = -0.73, P = 0.005, q = 0.01). There was also an association between total glutathione and APS (ρ = 0.56, P = 0.04, q = 0.25). Computational network analysis revealed a distinct metabolic pathway for each metabolite. In summary, this pilot study demonstrated the feasibility of plasma 1H-NMR quantitative metabolomics because it yielded a physiologically relevant metabolite data set that distinguished sepsis-induced ALI from health. In addition, it justifies the continued study of this approach to determine whether sepsis-induced ALI has a distinct metabolic phenotype and whether there are predictive biomarkers of severity and outcome in these patients. [ABSTRACT FROM AUTHOR]

Published

2011

4. MetDisease—connecting metabolites to diseases via literature.

Author

Duren, William, Weymouth, Terry, Hull, Tim, Omenn, Gilbert S., Athey, Brian, Burant, Charles, and Karnovsky, Alla

Subjects

METABOLITES, METABOLOMICS, BIOINFORMATICS, DISEASE research, MEDICAL subject headings

Abstract

Motivation: In recent years, metabolomics has emerged as an approach to perform large-scale characterization of small molecules in biological systems. Metabolomics posed a number of bioinformatics challenges associated in data analysis and interpretation. Genome-based metabolic reconstructions have established a powerful framework for connecting metabolites to genes through metabolic reactions and enzymes that catalyze them. Pathway databases and bioinformatics tools that use this framework have proven to be useful for annotating experimental metabolomics data. This framework can be used to infer connections between metabolites and diseases through annotated disease genes. However, only about half of experimentally detected metabolites can be mapped to canonical metabolic pathways. We present a new Cytoscape 3 plug-in, MetDisease, which uses an alternative approach to link metabolites to disease information. MetDisease uses Medical Subject Headings (MeSH) disease terms mapped to PubChem compounds through literature to annotate compound networks.Availability and implementation: MetDisease can be downloaded from http://apps.cytoscape.org/apps/metdisease or installed via the Cytoscape app manager. Further information about MetDisease can be found at http://metdisease.ncibi.orgContact: akarnovs@med.umich.eduSupplementary information: Supplementary Data are available at Bioinformatics online [ABSTRACT FROM AUTHOR]

Published

2014