Application of Screening Experimental Designs to Assess Chromatographic Isotope Effect upon Isotope-Coded Derivatization for Quantitative Liquid Chromatography–Mass Spectrometry

Szarka, Szabolcs; Prókai-Tátrai, Katalin; Prókai, László

doi:10.1021/ac501309s

Cited by 33 publications

(14 citation statements)

References 39 publications

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“…As with all MS analyses of complex samples, prior fractionation of mixtures is desired. The traditional tools of gas or liquid chromatography and electrophoresis broadly separate structural isomers, but never isotopomers (though LC can resolve non-isobaric isotopologues for various compounds, including labeled peptides) [13–14]. …”

Section: Introductionmentioning

confidence: 99%

Ion Mobility Separation of Peptide Isotopomers

Kaszycki

Bowman

Shvartsburg

2016

J. Am. Soc. Mass Spectrom.

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Differential or field asymmetric waveform ion mobility spectrometry (FAIMS) operating at high electric fields fully resolves isotopic isomers for a peptide with labeled residues. The naturally present isotopes, alone and together with targeted labels, also cause spectral shifts that approximately add for multiple heavy atoms. Separation qualitatively depends on the gas composition. These findings may enable novel strategies in proteomic and metabolomic analyses using stable isotope labeling.

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Section: Introductionmentioning

confidence: 99%

Ion Mobility Separation of Peptide Isotopomers

Kaszycki

Bowman

Shvartsburg

2016

J. Am. Soc. Mass Spectrom.

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“…Placing deuterium atoms in close proximity to a hydrophilic group decreases the chromatographic isotopic effect according to the solvophobic theory (Zhang, Sioma, Thompson, Xiong, & Regnier, ). By contrast, the chromatographic isotopic effect is insignificant in the case of 12 C/ 13 C, 16 O/ 18 O, and 14 N/ 15 N labeling because the chromatographic behavior of each pair of derivatives is the same (Szarka et al, ). Moreover, ICD is a labeling process, and thus, it carries the same disadvantage of any chemical derivatization process such as contamination of the ion source in the LC–MS system with the excess reagents or their by‐products, which may lead to ion suppression.…”

Section: Pros and Cons Of Isotope‐coded Derivatizationmentioning

confidence: 99%

“…The IS (heavy labeled derivatives) is mixed with the sample before LC-MS analysis, and so the recovery of the analyte is not corrected. As a consequence, the extraction and pre-treatment should be highly efficient (Hewavitharana, 2011;Szarka, Prokai-Tatrai, & Prokai, 2014;Yang, Mirzaei, Liu, & Regnier, 2006). In addition, the introduction of many 2 H atoms into the target compound causes a decrease in the retention behavior of the heavy isotope derivatized analytes in RPLC, exposing them to different matrix effects.…”

Section: Pros and Cons Of Isotope-coded Derivatizationmentioning

confidence: 99%

Current trends in isotope‐coded derivatization liquid chromatographic‐mass spectrometric analyses with special emphasis on their biomedical application

El-Maghrabey

Kishikawa

Kuroda

2020

Biomedical Chromatography

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Currently, LC–MS has various applications in different areas such as metabolomics, pharmacokinetics, and pathological studies. Yet, matrix effects resulting from co‐existing constituents remain a major problem for LC–MS [or LC–tandem mass spectrometry (LC–MS/MS)]. Moreover, technical problems and instrumental drifts may lead to ion abundance variance. Thus, an internal standard (IS) is required to guarantee the accuracy and precision of the method. Because of their limited number, isotope‐coded derivatization (ICD) has been recently introduced to overcome this problem. For ICD, a stable heavy isotope‐coded moiety is used for labeling the standard or the control sample and the formed products can act as ISs. A light form of the reagent is used for labeling the sample. Then, both are mixed and analyzed by LC–MS(/MS). This strategy permits the identification of different unknown analytes including potential metabolites and disease biomarkers. All these attributes lead to persistent growth in the applications of ICD LC–MS(/MS) in various biomedical branches. In this article we review the ICD methods published in the last eight years for biomedical applications as well as briefly summarize other applications for environmental and food analyses as some of their used ICD reagents were further applied for analyzing biological specimens or have the potential for that.

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“…The application of native and labeled sample mixtures in LC-HRMS-based untargeted metabolomics is implemented in many laboratories and is described as an effective method for detecting biology-derived metabolites and to improve (absolute, relative, or differential) quantification in metabolomics studies [5,[21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36]. To exemplify a few alternative approaches, the MIRACLE (Mass isotopomer ratio analysis of U 13 C-labeled extracts) approach, IROA (isotope ratio outlier analysis), and feature credentialing shall briefly be mentioned.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Metabolome Coverage and Evaluation of Matrix Effects by the Use of Experimental-Condition-Matched 13C-Labeled Biological Samples in Isotope-Assisted LC-HRMS Metabolomics

et al. 2020

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Stable isotope-assisted approaches can improve untargeted liquid chromatography-high resolution mass spectrometry (LC-HRMS) metabolomics studies. Here, we demonstrate at the example of chemically stressed wheat that metabolome-wide internal standardization by globally 13C-labeled metabolite extract (GLMe-IS) of experimental-condition-matched biological samples can help to improve the detection of treatment-relevant metabolites and can aid in the post-acquisition assessment of putative matrix effects in samples obtained upon different treatments. For this, native extracts of toxin- and mock-treated (control) wheat ears were standardized by the addition of uniformly 13C-labeled wheat ear extracts that were cultivated under similar experimental conditions (toxin-treatment and control) and measured with LC-HRMS. The results show that 996 wheat-derived metabolites were detected with the non-condition-matched 13C-labeled metabolite extract, while another 68 were only covered by the experimental-condition-matched GLMe-IS. Additional testing is performed with the assumption that GLMe-IS enables compensation for matrix effects. Although on average no severe matrix differences between both experimental conditions were found, individual metabolites may be affected as is demonstrated by wrong decisions with respect to the classification of significantly altered metabolites. When GLMe-IS was applied to compensate for matrix effects, 272 metabolites showed significantly altered levels between treated and control samples, 42 of which would not have been classified as such without GLMe-IS.

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Application of Screening Experimental Designs to Assess Chromatographic Isotope Effect upon Isotope-Coded Derivatization for Quantitative Liquid Chromatography–Mass Spectrometry

Cited by 33 publications

References 39 publications

Ion Mobility Separation of Peptide Isotopomers

Ion Mobility Separation of Peptide Isotopomers

Current trends in isotope‐coded derivatization liquid chromatographic‐mass spectrometric analyses with special emphasis on their biomedical application

Enhanced Metabolome Coverage and Evaluation of Matrix Effects by the Use of Experimental-Condition-Matched 13C-Labeled Biological Samples in Isotope-Assisted LC-HRMS Metabolomics

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