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Your search keyword '"Grant, David F."' showing total 16 results
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16 results on '"Grant, David F."'

1. Ion Mobility-Derived Collision Cross Section As an Additional Measure for Lipid Fingerprinting and Identification

Author

Paglia, Giuseppe, Angel, Peggi, Williams, Jonathan P, Richardson, Keith, Olivos, Hernando J, Thompson, J Will, Menikarachchi, Lochana, Lai, Steven, Walsh, Callee, Moseley, Arthur, Plumb, Robert S, Grant, David F, Palsson, Bernhard O, Langridge, James, Geromanos, Scott, and Astarita, Giuseppe

Subjects
Analytical Chemistry, Chemical Sciences, Physical Chemistry, Aged, Brain, Chromatography, Liquid, Humans, Lipids, Signal-To-Noise Ratio, Spectrometry, Mass, Secondary Ion, Other Chemical Sciences, Medical biochemistry and metabolomics, Analytical chemistry, Chemical engineering
Abstract

Despite recent advances in analytical and computational chemistry, lipid identification remains a significant challenge in lipidomics. Ion-mobility spectrometry provides an accurate measure of the molecules' rotationally averaged collision cross-section (CCS) in the gas phase and is thus related to ionic shape. Here, we investigate the use of CCS as a highly specific molecular descriptor for identifying lipids in biological samples. Using traveling wave ion mobility mass spectrometry (MS), we measured the CCS values of over 200 lipids within multiple chemical classes. CCS values derived from ion mobility were not affected by instrument settings or chromatographic conditions, and they were highly reproducible on instruments located in independent laboratories (interlaboratory RSD < 3% for 98% of molecules). CCS values were used as additional molecular descriptors to identify brain lipids using a variety of traditional lipidomic approaches. The addition of CCS improved the reproducibility of analysis in a liquid chromatography-MS workflow and maximized the separation of isobaric species and the signal-to-noise ratio in direct-MS analyses (e.g., "shotgun" lipidomics and MS imaging). These results indicate that adding CCS to databases and lipidomics workflows increases the specificity and selectivity of analysis, thus improving the confidence in lipid identification compared to traditional analytical approaches. The CCS/accurate-mass database described here is made publicly available.

Published
2015

10. In Silico Enzymatic Synthesis of a 400 000 Compound Biochemical Database for Nontargeted Metabolomics

Author

Menikarachchi, Lochana C., Hill, Dennis W., Hamdalla, Mai A., Mandoiu, Ion I., and Grant, David F.

Abstract

Current methods of structure identification in mass-spectrometry-based nontargeted metabolomics rely on matching experimentally determined features of an unknown compound to those of candidate compounds contained in biochemical databases. A major limitation of this approach is the relatively small number of compounds currently included in these databases. If the correct structure is not present in a database, it cannot be identified, and if it cannot be identified, it cannot be included in a database. Thus, there is an urgent need to augment metabolomics databases with rationally designed biochemical structures using alternative means. Here we present the In Vivo/In Silico Metabolites Database (IIMDB), a database of in silico enzymatically synthesized metabolites, to partially address this problem. The database, which is available at http://metabolomics.pharm.uconn.edu/iimdb/, includes ∼23 000 known compounds (mammalian metabolites, drugs, secondary plant metabolites, and glycerophospholipids) collected from existing biochemical databases plus more than 400 000 computationally generated human phase-I and phase-II metabolites of these known compounds. IIMDB features a user-friendly web interface and a programmer-friendly RESTful web service. Ninety-five percent of the computationally generated metabolites in IIMDB were not found in any existing database. However, 21 640 were identical to compounds already listed in PubChem, HMDB, KEGG, or HumanCyc. Furthermore, the vast majority of these in silico metabolites were scored as biological using BioSM, a software program that identifies biochemical structures in chemical structure space. These results suggest that in silico biochemical synthesis represents a viable approach for significantly augmenting biochemical databases for nontargeted metabolomics applications.

Published
2024
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14. Ion Mobility-Derived Collision Cross Section As an Additional Measure for Lipid Fingerprinting and Identification

Author

Paglia, Giuseppe, primary, Angel, Peggi, additional, Williams, Jonathan P., additional, Richardson, Keith, additional, Olivos, Hernando J., additional, Thompson, J. Will, additional, Menikarachchi, Lochana, additional, Lai, Steven, additional, Walsh, Callee, additional, Moseley, Arthur, additional, Plumb, Robert S., additional, Grant, David F., additional, Palsson, Bernhard O., additional, Langridge, James, additional, Geromanos, Scott, additional, and Astarita, Giuseppe, additional

Published
2014
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15. MolFind 2 : A Protocol for Acquiring and Integrating MS 3 Data to Improve In Silico Chemical Structure Elucidation for Metabolomics.

Author

Samaraweera MA, Hill DW, and Grant DF

Subjects
Databases, Chemical, Molecular Structure, Computational Biology methods, Metabolomics methods, Software, Tandem Mass Spectrometry methods
Abstract

Structure elucidation of metabolites (<1000 Da) in biofluids is extremely challenging due to the diversity and complexity of chemical structure space. Generally, due to lack of reference tandem mass data (MS 2 ), in silico fragmenters are used to rank candidates acquired from chemical databases as a function on how well they explain an experimental collision-induced dissociation spectrum. However, multistage fragmentation data (i.e., MS 3 ) have not been adequately utilized in current metabolomics structure elucidation pipelines. To address this shortcoming, here we describe an experimental (nontargeted direct infusion ion mobility-mass spectrometry-based) and computational workflow to acquire and utilize multistage mass (MS 3 ) spectrometry data for database-assisted structure elucidation.

Published
2020
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16. Development of Database Assisted Structure Identification (DASI) Methods for Nontargeted Metabolomics.

Author

Menikarachchi LC, Dubey R, Hill DW, Brush DN, and Grant DF

Abstract

Metabolite structure identification remains a significant challenge in nontargeted metabolomics research. One commonly used strategy relies on searching biochemical databases using exact mass. However, this approach fails when the database does not contain the unknown metabolite (i.e., for unknown-unknowns). For these cases, constrained structure generation with combinatorial structure generators provides a potential option. Here we evaluated structure generation constraints based on the specification of: (1) substructures required (i.e., seed structures); (2) substructures not allowed; and (3) filters to remove incorrect structures. Our approach (database assisted structure identification, DASI) used predictive models in MolFind to find candidate structures with chemical and physical properties similar to the unknown. These candidates were then used for seed structure generation using eight different structure generation algorithms. One algorithm was able to generate correct seed structures for 21/39 test compounds. Eleven of these seed structures were large enough to constrain the combinatorial structure generator to fewer than 100,000 structures. In 35/39 cases, at least one algorithm was able to generate a correct seed structure. The DASI method has several limitations and will require further experimental validation and optimization. At present, it seems most useful for identifying the structure of unknown-unknowns with molecular weights <200 Da.

Published
2016
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