Closed-loop, multiobjective optimization of two-dimensional gas chromatography/mass spectrometry for serum metabolomics

Steve O'Hagan; Warwick B. Dunn; Joshua D. Knowles; David Broadhurst; Rebecca Williams; Jason J. Ashworth; Maureen Cameron; Douglas B. Kell

doi:10.1021/ac061443+

Closed-loop, multiobjective optimization of two-dimensional gas chromatography/mass spectrometry for serum metabolomics

Steve O'Hagan, Warwick B. Dunn, Joshua D. Knowles, David Broadhurst, Rebecca Williams, Jason J. Ashworth, Maureen Cameron, Douglas B. Kell

Research output: Contribution to journal › Article › peer-review

Abstract

Metabolomics seeks to measure potentially all the metabolites in a biological sample, and consequently, we need to develop and optimize methods to increase significantly the number of metabolites we can detect. We extended the closed-loop (iterative, automated) optimization system that we had previously developed for one-dimensional GC-TOF-MS (O'Hagan, S.; Dunn, W. B.; Brown, M.; Knowles, J. D.; Kell, D. B. Anal. Chem. 2005, 77, 290-303) to comprehensive two-dimensional (GC × GC) chromatography. The heuristic approach used was a multiobjective version of the efficient global optimization algorithm. In just 300 automated runs, we improved the number of metabolites observable relative to those in 1D GC by some 3-fold. The optimized conditions allowed for the detection of over 4000 raw peaks, of which some 1800 were considered to be real metabolite peaks and not impurities or peaks with a signal/noise ratio of less than 5. A variety of computational methods served to explain the basis for the improvement. This closed-loop optimization strategy is a generic and powerful approach for the optimization of any analytical instrumentation. © 2007 American Chemical Society.

Original language	English
Pages (from-to)	464-476
Number of pages	12
Journal	Analytical Chemistry
Volume	79
Issue number	2
DOIs	https://doi.org/10.1021/ac061443+
Publication status	Published - 15 Jan 2007

Keywords

Biological Markers/*blood/metabolism
Gas Chromatography-Mass Spectrometry/*methods/*standards
Humans

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title = "Closed-loop, multiobjective optimization of two-dimensional gas chromatography/mass spectrometry for serum metabolomics",

abstract = "Metabolomics seeks to measure potentially all the metabolites in a biological sample, and consequently, we need to develop and optimize methods to increase significantly the number of metabolites we can detect. We extended the closed-loop (iterative, automated) optimization system that we had previously developed for one-dimensional GC-TOF-MS (O'Hagan, S.; Dunn, W. B.; Brown, M.; Knowles, J. D.; Kell, D. B. Anal. Chem. 2005, 77, 290-303) to comprehensive two-dimensional (GC × GC) chromatography. The heuristic approach used was a multiobjective version of the efficient global optimization algorithm. In just 300 automated runs, we improved the number of metabolites observable relative to those in 1D GC by some 3-fold. The optimized conditions allowed for the detection of over 4000 raw peaks, of which some 1800 were considered to be real metabolite peaks and not impurities or peaks with a signal/noise ratio of less than 5. A variety of computational methods served to explain the basis for the improvement. This closed-loop optimization strategy is a generic and powerful approach for the optimization of any analytical instrumentation. {\textcopyright} 2007 American Chemical Society.",

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author = "Steve O'Hagan and Dunn, {Warwick B.} and Knowles, {Joshua D.} and David Broadhurst and Rebecca Williams and Ashworth, {Jason J.} and Maureen Cameron and Kell, {Douglas B.}",

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AU - O'Hagan, Steve

AU - Dunn, Warwick B.

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AU - Broadhurst, David

AU - Williams, Rebecca

AU - Ashworth, Jason J.

AU - Cameron, Maureen

AU - Kell, Douglas B.

N1 - O'Hagan, Steve Dunn, Warwick B Knowles, Joshua D Broadhurst, David Williams, Rebecca Ashworth, Jason J Cameron, Maureen Kell, Douglas B Research Support, Non-U.S. Gov't United States Analytical chemistry Anal Chem. 2007 Jan 15;79(2):464-76.

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N2 - Metabolomics seeks to measure potentially all the metabolites in a biological sample, and consequently, we need to develop and optimize methods to increase significantly the number of metabolites we can detect. We extended the closed-loop (iterative, automated) optimization system that we had previously developed for one-dimensional GC-TOF-MS (O'Hagan, S.; Dunn, W. B.; Brown, M.; Knowles, J. D.; Kell, D. B. Anal. Chem. 2005, 77, 290-303) to comprehensive two-dimensional (GC × GC) chromatography. The heuristic approach used was a multiobjective version of the efficient global optimization algorithm. In just 300 automated runs, we improved the number of metabolites observable relative to those in 1D GC by some 3-fold. The optimized conditions allowed for the detection of over 4000 raw peaks, of which some 1800 were considered to be real metabolite peaks and not impurities or peaks with a signal/noise ratio of less than 5. A variety of computational methods served to explain the basis for the improvement. This closed-loop optimization strategy is a generic and powerful approach for the optimization of any analytical instrumentation. © 2007 American Chemical Society.

AB - Metabolomics seeks to measure potentially all the metabolites in a biological sample, and consequently, we need to develop and optimize methods to increase significantly the number of metabolites we can detect. We extended the closed-loop (iterative, automated) optimization system that we had previously developed for one-dimensional GC-TOF-MS (O'Hagan, S.; Dunn, W. B.; Brown, M.; Knowles, J. D.; Kell, D. B. Anal. Chem. 2005, 77, 290-303) to comprehensive two-dimensional (GC × GC) chromatography. The heuristic approach used was a multiobjective version of the efficient global optimization algorithm. In just 300 automated runs, we improved the number of metabolites observable relative to those in 1D GC by some 3-fold. The optimized conditions allowed for the detection of over 4000 raw peaks, of which some 1800 were considered to be real metabolite peaks and not impurities or peaks with a signal/noise ratio of less than 5. A variety of computational methods served to explain the basis for the improvement. This closed-loop optimization strategy is a generic and powerful approach for the optimization of any analytical instrumentation. © 2007 American Chemical Society.

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ER -

Closed-loop, multiobjective optimization of two-dimensional gas chromatography/mass spectrometry for serum metabolomics

Abstract

Keywords

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