Simple data-reduction method for high-resolution LC - MS data in metabolomics

R. A. Scheltema; S. Decuypere; J. C. Dujardin; D. G. Watson; R. C. Jansen; R. Breitling

doi:10.4155/bio.09.146

Simple data-reduction method for high-resolution LC - MS data in metabolomics

R. A. Scheltema, S. Decuypere, J. C. Dujardin, D. G. Watson, R. C. Jansen, R. Breitling

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Abstract

Background: Metabolomics LC - MS experiments yield large numbers of peaks, few of which can be identified by database matching. Many of the remaining peaks correspond to derivatives of identified peaks (e.g., isotope peaks, adducts, fragments and multiply charged molecules). In this article, we present a data-reduction approach that automatically identifies these derivative peaks. Results: Using data-driven clustering based on chromatographic peak shape correlation and intensity patterns across biological replicates, derivative peaks can be reliably identified. Using a test data set obtained from Leishmania donovani extracts, we achieved a 60% reduction of the number of peaks. After quality control filtering, almost 80% of the peaks could putatively be identified by database matching. Conclusion: Automated peak filtering substantially speeds up the data-interpretation process. © 2009 Future Science Ltd.

Original language	English
Pages (from-to)	1551-1557
Number of pages	6
Journal	Bioanalysis
Volume	1
Issue number	9
DOIs	https://doi.org/10.4155/bio.09.146
Publication status	Published - 2009

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@article{a39e2c472904460184698839bdab1e53,

title = "Simple data-reduction method for high-resolution LC - MS data in metabolomics",

abstract = "Background: Metabolomics LC - MS experiments yield large numbers of peaks, few of which can be identified by database matching. Many of the remaining peaks correspond to derivatives of identified peaks (e.g., isotope peaks, adducts, fragments and multiply charged molecules). In this article, we present a data-reduction approach that automatically identifies these derivative peaks. Results: Using data-driven clustering based on chromatographic peak shape correlation and intensity patterns across biological replicates, derivative peaks can be reliably identified. Using a test data set obtained from Leishmania donovani extracts, we achieved a 60% reduction of the number of peaks. After quality control filtering, almost 80% of the peaks could putatively be identified by database matching. Conclusion: Automated peak filtering substantially speeds up the data-interpretation process. {\textcopyright} 2009 Future Science Ltd.",

author = "Scheltema, {R. A.} and S. Decuypere and Dujardin, {J. C.} and Watson, {D. G.} and Jansen, {R. C.} and R. Breitling",

year = "2009",

doi = "10.4155/bio.09.146",

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volume = "1",

pages = "1551--1557",

journal = "Bioanalysis",

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TY - JOUR

T1 - Simple data-reduction method for high-resolution LC - MS data in metabolomics

AU - Scheltema, R. A.

AU - Decuypere, S.

AU - Dujardin, J. C.

AU - Watson, D. G.

AU - Jansen, R. C.

AU - Breitling, R.

PY - 2009

Y1 - 2009

N2 - Background: Metabolomics LC - MS experiments yield large numbers of peaks, few of which can be identified by database matching. Many of the remaining peaks correspond to derivatives of identified peaks (e.g., isotope peaks, adducts, fragments and multiply charged molecules). In this article, we present a data-reduction approach that automatically identifies these derivative peaks. Results: Using data-driven clustering based on chromatographic peak shape correlation and intensity patterns across biological replicates, derivative peaks can be reliably identified. Using a test data set obtained from Leishmania donovani extracts, we achieved a 60% reduction of the number of peaks. After quality control filtering, almost 80% of the peaks could putatively be identified by database matching. Conclusion: Automated peak filtering substantially speeds up the data-interpretation process. © 2009 Future Science Ltd.

AB - Background: Metabolomics LC - MS experiments yield large numbers of peaks, few of which can be identified by database matching. Many of the remaining peaks correspond to derivatives of identified peaks (e.g., isotope peaks, adducts, fragments and multiply charged molecules). In this article, we present a data-reduction approach that automatically identifies these derivative peaks. Results: Using data-driven clustering based on chromatographic peak shape correlation and intensity patterns across biological replicates, derivative peaks can be reliably identified. Using a test data set obtained from Leishmania donovani extracts, we achieved a 60% reduction of the number of peaks. After quality control filtering, almost 80% of the peaks could putatively be identified by database matching. Conclusion: Automated peak filtering substantially speeds up the data-interpretation process. © 2009 Future Science Ltd.

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DO - 10.4155/bio.09.146

M3 - Article

SN - 1757-6180

VL - 1

SP - 1551

EP - 1557

JO - Bioanalysis

JF - Bioanalysis

IS - 9

ER -

Simple data-reduction method for high-resolution LC - MS data in metabolomics

Abstract

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