Discriminating precursors of common fragments for large-scale metabolite profiling by triple quadrupole mass spectrometry

Nikolskiy, Igor; Siuzdak, Gary; Patti, Gary J.

doi:10.1093/bioinformatics/btv085

Cited by 19 publications

(16 citation statements)

References 20 publications

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“…Previously, we determined the most unique precursor-to-product transitions that could be used to construct the fewest number of MRMs for profiling all metabolites in METLIN. 21 We used these informative fragments as the basis for selecting bins. In brief, we optimized the combination of bins that enabled us to resolve as many compounds with MS 2 spectra in METLIN as possible within 0.1 Da.…”

Section: Resultsmentioning

confidence: 99%

Bar Coding MS² Spectra for Metabolite Identification

et al. 2016

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Metabolite identifications are most frequently achieved in untargeted metabolomics by matching precursor mass and full, high-resolution MS2 spectra to metabolite databases and standards. Here we considered an alternative approach for establishing metabolite identifications that does not rely on full, high-resolution MS2 spectra. First, we select mass-to-charge regions containing the most informative metabolite fragments and designate them as bins. We then translate each metabolite fragmentation pattern into a binary code by assigning 1’s to bins containing fragments and 0’s to bins without fragments. With 20 bins, this binary-code system is capable of distinguishing 96% of the compounds in the METLIN MS2 library. A major advantage of the approach is that it extends untargeted metabolomics to low-resolution triple quadrupole (QqQ) instruments, which are typically less expensive and more robust than other types of mass spectrometers. We demonstrate a method of acquiring MS2 data in which the third quadrupole of a QqQ instrument cycles over 20 wide isolation windows (coinciding with the location and width of our bins) for each precursor mass selected by the first quadrupole. Operating the QqQ instrument in this mode yields diagnostic bar codes for each precursor mass that can be matched to the bar codes of metabolite standards. Furthermore, our data suggest that using low-resolution bar codes enables QqQ instruments to make MS2-based identifications in untargeted metabolomics with a specificity and sensitivity that is competitive to high-resolution time-of-flight technologies.

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Section: Resultsmentioning

confidence: 99%

Bar Coding MS² Spectra for Metabolite Identification

et al. 2016

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“…This has been applied in the field of proteomics as digital biobanking of proteomes [ 255 ]. In contrast to the field of proteomics and metabolomics in which the use of open source software as well as open standards for mass spectrometry data has been widespread [ [256] , [257] , [258] , [259] ], the use of mass spectrometry in clinical laboratory remained mostly within the framework of manufacturer-provided software as most applications of mass spectrometry in the clinical laboratory calls for selective quantitation of analytes rather than omic-profiling and data-mining. One starting point for a beginner in mass spectrometry data analysis is bioconductor ( http://bioconductor.org /), an open source platform for bioinformatics data analysis [ 260 , 261 ].…”

Section: Clinical Mass Spectrometrymentioning

confidence: 99%

Clinical Mass Spectrometry in the Bioinformatics Era: A Hitchhiker’s Guide

Chong

Leung

et al. 2018

Computational and Structural Biotechnology Journal

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Mass spectrometry (MS) is a sensitive, specific and versatile analytical technique in the clinical laboratory that has recently undergone rapid development. From initial use in metabolic profiling, it has matured into applications including clinical toxicology assays, target hormone and metabolite quantitation, and more recently, rapid microbial identification and antimicrobial resistance detection by matrix assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS). In this mini-review, we first succinctly outline the basics of clinical mass spectrometry. Examples of hard ionization (electron ionization) and soft ionization (electrospray ionization, MALDI) are presented to demonstrate their clinical applications. Next, a conceptual discourse on mass selection and determination is presented: quadrupole mass filter, time-of-flight mass spectrometer and the Orbitrap; and MS/MS (tandem-in-space, tandem-in-time and data acquisition), illustrated with clinical examples. Current applications in (1) bacterial and fungal identification, antimicrobial susceptibility testing and phylogenetic classification, (2) general unknown urine toxicology screening and expanded new-born metabolic screening and (3) clinical metabolic profiling by gas chromatography are outlined. Finally, major limitations of MS-based techniques, including the technical challenges of matrix effect and isobaric interference; and novel challenges in the post-genomic era, such as protein molecular variants, are critically discussed from the perspective of service laboratories. Computer technology and structural biology have played important roles in the maturation of this field. MS-based techniques have the potential to replace current analytical techniques, and existing expertise and instrument will undergo rapid evolution. Significant automation and adaptation to regulatory requirements are underway. Mass spectrometry is unleashing its potentials in clinical laboratories.

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“…Then, the molecular mass of the predicted structure (m/z value) was detected by XIC, and the extracted peak (if existed) was subsequently identified by MS data to confirm the result. Taking 65 (licoricesaponin E2) and 66 (glabrolid) in liquorice as an example, the predominant quasimolecular ion [M-H] − at m/z 819.3839 of peak 65 gave the formula C 42 H 60 O 16 , and its fragment ions at m/z 643.3555 (a C 6 H 8 O 6 loss) and 467.3203 (two C 6 H 8 O 6 losses) suggested successive losses of glucuronosyl moieties. A CO 2 loss from C 30 H 44 O 4 (m/z 467.3203) also indicated a potential ester moiety.…”

Section: Tfnt Strategy For Comprehensive Chemical Identification Of Hmentioning

confidence: 99%

Deciphering chemical interactions between Glycyrrhizae Radix and Coptidis Rhizoma by liquid chromatography with transformed multiple reaction monitoring mass spectrometry

Liu

Liao

et al. 2017

J. Sep. Sci.

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In this study, we propose an integrated strategy for the efficient identification and quantification of herbal constituents using liquid chromatography with mass spectrometry. First, liquid chromatography with quadrupole time-of-flight mass spectrometry was employed for the chemical profiling of herbs, where a targeted following nontargeted approach was developed to detect trace constituents by using structural correlations and extracted ion chromatograms. Next, ion pairs and parameters of MS of quadrupole time-of-flight mass spectrometry were selected to design multiple reaction monitoring transitions for the identified compounds on liquid chromatography with triple quadrupole mass spectrometry. The relative concentration of each constituent was then calculated using a semiquantitative calibration curve. The proposed strategy was applied in a study of chemical interactions between Glycyrrhizae Radix and Coptidis Rhizoma. A total of 140 compounds were identified or tentatively characterized from the herbs, 132 of which were relatively quantified. The visualized quantitative results clearly showed codecoction produced significant constituent concentration variations especially for those with a low polarity. The case study also indicated that the present methodology could provide a reliable, accurate, and labor-saving solution for chemical studies of herbal medicines.

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Discriminating precursors of common fragments for large-scale metabolite profiling by triple quadrupole mass spectrometry

Cited by 19 publications

References 20 publications

Bar Coding MS² Spectra for Metabolite Identification

Bar Coding MS² Spectra for Metabolite Identification

Clinical Mass Spectrometry in the Bioinformatics Era: A Hitchhiker’s Guide

Deciphering chemical interactions between Glycyrrhizae Radix and Coptidis Rhizoma by liquid chromatography with transformed multiple reaction monitoring mass spectrometry

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Discriminating precursors of common fragments for large-scale metabolite profiling by triple quadrupole mass spectrometry

Cited by 19 publications

References 20 publications

Bar Coding MS2 Spectra for Metabolite Identification

Bar Coding MS2 Spectra for Metabolite Identification

Clinical Mass Spectrometry in the Bioinformatics Era: A Hitchhiker’s Guide

Deciphering chemical interactions between Glycyrrhizae Radix and Coptidis Rhizoma by liquid chromatography with transformed multiple reaction monitoring mass spectrometry

Contact Info

Product

Resources

About

Bar Coding MS² Spectra for Metabolite Identification

Bar Coding MS² Spectra for Metabolite Identification