A batch correction method for liquid chromatography–mass spectrometry data that does not depend on quality control samples

Rusilowicz, Martin; Dickinson, Mike; Charlton, Adrian J.; O’Keefe, Simon; Wilson, Julie

doi:10.1007/s11306-016-0972-2

Cited by 48 publications

(45 citation statements)

References 26 publications

(32 reference statements)

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“…Quality control (QC, pooled plasma) samples were subjected to the same preparation protocol and injected every 10 and 5 samples for GC-MS and LC-MS analysis, respectively. Each metabolite's signals were normalized with a QC-based correction method using the smooth-spline algorithm (43)(44)(45). Information on all the measured metabolites, including retention time, m/z, and ion transitions, is summarized in Supplemental Tables 2 and 3.…”

Section: L I N I C a L M E D I C I N Ementioning

confidence: 99%

Combination of host immune metabolic biomarkers for the PD-1 blockade cancer immunotherapy

Hatae¹,

Chamoto²,

Kim³

et al. 2020

JCI Insight

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Section: L I N I C a L M E D I C I N Ementioning

confidence: 99%

Combination of host immune metabolic biomarkers for the PD-1 blockade cancer immunotherapy

Hatae¹,

Chamoto²,

Kim³

et al. 2020

JCI Insight

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“…The first three methods, quadratic fit (QUAD), cubic splines fit (CUBSPL), and LOESS, use QC samples to correct for within- and between-batch drift. QC-sample-based drift correction is performed by adjusting raw peak area according to the equation [36, 37]:…”

Section: Methodsmentioning

confidence: 99%

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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“…Thus, in order to conclude a biologically relevant hypothesis, the biological difference between two or more sample groups needs to be larger than the analytical variance within and between each batch, hence reproducibility is of utmost importance (Van Der Kloet et al 2009;Zelena et al 2009). Worth noting here is the progress made concerning signal correction based on mathematical models which has the potential to correct for batch-to-batch variations as well as instrumental drift (Draisma et al 2010;Dunn et al 2011;Hendriks et al 2011;Kamleh et al 2012;Kuligowski et al 2015;Rusilowicz et al 2016;Van Der Kloet et al 2009;Wehrens et al 2016).…”

Section: Evaluation Of Data Qualitymentioning

confidence: 99%

LC–MS based global metabolite profiling: the necessity of high data quality

et al. 2016

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LC-MS based global metabolite profiling currently lacks detailed guidelines to demonstrate that the obtained data is of high enough analytical quality. Insufficient data quality may result in the failure to generate a hypothesis, or in the worst case, a false or skewed hypothesis. After assessing the literature, it is apparent that an analytically focused summary and critical discussion related to this subject would be beneficial for both beginners and experts engaged in this field. A particular focus will be placed on data quality, which we here define as the degree to which a set of parameters fulfills predetermined criteria, similar to the established guidelines for targeted analysis. However, several of these parameters are difficult to assess since holistic approaches measure thousands of metabolites in parallel and seldom include predefined knowledge of which metabolites will differ between sample groups. In this review, the following parameters will be discussed in detail: reproducibility, selectivity, certainty of metabolite identification and metabolite coverage. The review systematically describes the generic workflow for LC-MS based global metabolite profiling and highlights how each separate part may affect data quality. The last part of the review describes how data quality can be evaluated as well as identifies areas where additional improvement is needed. In this review, we provide our own analytical opinions in regards to evaluation and, to some extent, improvement of data quality.

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A batch correction method for liquid chromatography–mass spectrometry data that does not depend on quality control samples

Cited by 48 publications

References 26 publications

Combination of host immune metabolic biomarkers for the PD-1 blockade cancer immunotherapy

Combination of host immune metabolic biomarkers for the PD-1 blockade cancer immunotherapy

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

LC–MS based global metabolite profiling: the necessity of high data quality

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