Improved batch correction in untargeted MS-based metabolomics

Wehrens, Ron; Hageman, Jos A.; Eeuwijk, Fred van; Kooke, Rik; Flood, Pádraic J.; Wijnker, Erik; Keurentjes, Joost J. B.; Lommen, Arjen; Eekelen, Henriëtte D. L. M. van; Hall, Robert D.; Mumm, Roland; Vos, Ric C. H. de

doi:10.1007/s11306-016-1015-8

Cited by 181 publications

(153 citation statements)

References 37 publications

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“…The likely explanation is overfitting, a phenomenon in which fitting of random noise in the QC sample data results in introduction of additional noise into the corrected data. This phenomenon has been observed previously by others in this and similar contexts [9, 42] and is visually illustrated in Figure 2B, in which the CUBSPL curve perfectly fits the profile of the QC sample intensity, in spite of the fact that much of the sample-to-sample variation is likely due to noise. A similar effect is likely to occur for LOESS curve fitting when the smoothing parameter, α, is set too low.…”

Section: Resultssupporting

confidence: 86%

Evaluation of intensity drift correction strategies using MetaboDrift, a normalization tool for multi-batch metabolomics data

Thonusin

IglayReger

Soni

et al. 2017

Journal of Chromatography A

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In recent years, mass spectrometry-based metabolomics has increasingly been applied to large-scale epidemiological studies of human subjects. However, the successful use of metabolomics in this context is subject to the challenge of detecting biologically significant effects despite substantial intensity drift that often occurs when data are acquired over a long period or in multiple batches. Numerous computational strategies and software tools have been developed to aid in correcting for intensity drift in metabolomics data, but most of these techniques are implemented using command-line driven software and custom scripts which are not accessible to all end users of metabolomics data. Further, it has not yet become routine practice to assess the quantitative accuracy of drift correction against techniques which enable true absolute quantitation such as isotope dilution mass spectrometry. We developed an Excel-based tool, MetaboDrift, to visually evaluate and correct for intensity drift in a multi-batch liquid chromatography -mass spectrometry (LC-MS) metabolomics dataset. The tool enables drift correction based on either quality control (QC) samples analyzed throughout the batches or using QC-sample independent methods. We applied MetaboDrift to an original set of clinical metabolomics data from a mixed-meal tolerance test (MMTT). The performance of the method was evaluated for multiple classes of metabolites by comparison with normalization using isotope-labeled internal standards. QC sample-based intensity drift correction significantly improved correlation with IS-normalized data, and resulted in detection of additional metabolites with significant physiological response to the MMTT. The relative merits of different QC-sample curve fitting strategies are discussed in the context of batch size and drift pattern complexity. Our drift correction tool offers a practical, simplified approach to drift correction and batch combination in large metabolomics studies.

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Section: Resultssupporting

confidence: 86%

Evaluation of intensity drift correction strategies using MetaboDrift, a normalization tool for multi-batch metabolomics data

Thonusin

IglayReger

Soni

et al. 2017

Journal of Chromatography A

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“…Intrabatch variability, usually due to drift in instrument performance during the analytical run, was corrected in an approach similar to Wehrens et al [24]. In detail, we applied robust linear regression [25] to estimate the injection orderdependent signal drift for each feature based on the intensities measured in all samples (since the sample order in the run was randomized) and subsequently adjusted the intensities based on the fitted model.…”

Section: Discussionmentioning

confidence: 99%

Pre-analytic evaluation of volumetric absorptive microsampling and integration in a mass spectrometry-based metabolomics workflow

et al. 2017

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Volumetric absorptive microsampling (VAMS) is a novel approach that allows single-drop (10 μL) blood collection. Integration of VAMS with mass spectrometry (MS)-based untargeted metabolomics is an attractive solution for both human and animal studies. However, to boost the use of VAMS in metabolomics, key pre-analytical questions need to be addressed. Therefore, in this work, we integrated VAMS in a MS-based untargeted metabolomics workflow and investigated pre-analytical strategies such as sample extraction procedures and metabolome stability at different storage conditions. We first evaluated the best extraction procedure for the polar metabolome and found that the highest number and amount of metabolites were recovered upon extraction with acetonitrile/water (70:30). In contrast, basic conditions (pH 9) resulted in divergent metabolite profiles mainly resulting from the extraction of intracellular metabolites originating from red blood cells. In addition, the prolonged storage of blood samples at room temperature caused significant changes in metabolome composition, but once the VAMS devices were stored at − 80 °C, the metabolome remained stable for up to 6 months. The time used for drying the sample did also affect the metabolome. In fact, some metabolites were rapidly degraded or accumulated in the sample during the first 48 h at room temperature, indicating that a longer drying step will significantly change the concentration in the sample. KeywordsMetabolomics; Volumetric absorptive microsampling; Mass spectrometry ✉ Giuseppe Paglia beppepaglia@gmail.com. Compliance with ethical standardsThis study was performed in accordance with the ethical standards. The local ethics committee (Comitato etico del comprensorio sanitario di Bolzano) approved the study, and all participants provided written informed consent.

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“…When carrying out analyses in the absence of these standards, we therefore recommend making comparisons using material from a similar origin (compare serum A to serum B or tumor A to tumor B) and as similiar an amount of material as possible. Alternatively, pooled quality control samples can be used to reduce variation due to batch effects[66] . When applying these principles, most MRM and HRMS methods have yielded a linear range of quantitation for 3 to 4 orders of magnitude.…”

Section: From Mass Spectrometry Data To Metabolite Profilingmentioning

confidence: 99%

Metabolomics: A Primer

Liu

Locasale

2017

Trends in Biochemical Sciences

279

192

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Metabolomics generates a profile of small molecules that are derived from cellular metabolism and can directly reflect the outcome of complex networks of biochemical reactions, thus providing insights into multiple aspects of cellular physiology. Technological advances have enabled rapid and increasingly expansive data acquisition with samples as small as single cells; however substantial difficulties remain. In this primer, we provide an overview of metabolomics, especially mass spectrometry based metabolomics that uses liquid chromatography for separation, and discuss its utilities and limitations. We identify several areas at the frontier of metabolomics technology development. Our goal is to give the reader a sense of what might be accomplished when conducting a metabolomics experiment, now and in the near future.

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Improved batch correction in untargeted MS-based metabolomics

Cited by 181 publications

References 37 publications

Evaluation of intensity drift correction strategies using MetaboDrift, a normalization tool for multi-batch metabolomics data

Evaluation of intensity drift correction strategies using MetaboDrift, a normalization tool for multi-batch metabolomics data

Pre-analytic evaluation of volumetric absorptive microsampling and integration in a mass spectrometry-based metabolomics workflow

Metabolomics: A Primer

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