Metabolite Identification Using Automated Comparison of High-Resolution Multistage Mass Spectral Trees

Metabolite Identification Using Automated Comparison of High-Resolution Multistage Mass Spectral Trees

Multistage mass spectrometry (MS n ) generating so-called spectral trees is a powerful tool in the annotation and structural elucidation of metabolites and is increasingly used in the area of accurate mass LC/MS-based metabolomics to identify unknown, but biologically relevant, compounds. As a conse...

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Bibliographic Details
Published in:Analytical chemistry (Washington) Vol. 84; no. 13; pp. 5524 - 5534
Main Authors: Rojas-Cherto, Miquel, Peironcely, Julio E, Kasper, Piotr T, van der Hooft, Justin J. J, de Vos, Ric C. H, Vreeken, Rob, Hankemeier, Thomas, Reijmers, Theo
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 03-07-2012
Subjects:
algorithms
Analytical chemistry
chemical markup
Chemistry
Chromans - chemistry
Chromans - metabolism
Comparative analysis
Correlation analysis
Databases, Factual
development kit cdk
Exact sciences and technology
Flavones - chemistry
Flavones - metabolism
fragmentation
General, instrumentation
Humans
Hydroxylysine - chemistry
Hydroxylysine - metabolism
instruments
Mass spectrometry
Mass Spectrometry - methods
Metabolites
Metabolome
Metabolomics - methods
ms/ms
optimization
Plants - metabolism
source java library
Spectrometric and optical methods
spectrometry data
Uric Acid - analogs & derivatives
Uric Acid - chemistry
Uric Acid - metabolism
web
Human
Resolving power
Metabolomics
Automation
High resolution
Fourier transform spectroscopy
Vegetals
Metabolite
Coupled method
Use
Instrumentation
Identification
Substructure
Replica method
De novo
Fragmentation
Automatic processing
Design
Plant
Library
Mass spectrometry
Comparative study
Tool
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Description
Summary:Multistage mass spectrometry (MS n ) generating so-called spectral trees is a powerful tool in the annotation and structural elucidation of metabolites and is increasingly used in the area of accurate mass LC/MS-based metabolomics to identify unknown, but biologically relevant, compounds. As a consequence, there is a growing need for computational tools specifically designed for the processing and interpretation of MS n data. Here, we present a novel approach to represent and calculate the similarity between high-resolution mass spectral fragmentation trees. This approach can be used to query multiple-stage mass spectra in MS spectral libraries. Additionally the method can be used to calculate structure–spectrum correlations and potentially deduce substructures from spectra of unknown compounds. The approach was tested using two different spectral libraries composed of either human or plant metabolites which currently contain 872 MS n spectra acquired from 549 metabolites using Orbitrap FTMS n . For validation purposes, for 282 of these 549 metabolites, 765 additional replicate MS n spectra acquired with the same instrument were used. Both the dereplication and de novo identification functionalities of the comparison approach are discussed. This novel MS n spectral processing and comparison approach increases the probability to assign the correct identity to an experimentally obtained fragmentation tree. Ultimately, this tool may pave the way for constructing and populating large MS n spectral libraries that can be used for searching and matching experimental MS n spectra for annotation and structural elucidation of unknown metabolites detected in untargeted metabolomics studies.
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SourceType-Scholarly Journals-1
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ISSN:0003-2700
1520-6882
DOI:10.1021/ac2034216