A Novel Lipidomics Workflow for Improved Human Plasma Identification and Quantification Using RPLC-MSn Methods and Isotope Dilution Strategies

A Novel Lipidomics Workflow for Improved Human Plasma Identification and Quantification Using RPLC-MSn Methods and Isotope Dilution Strategies

Lipid identification and quantification are essential objectives in comprehensive lipidomics studies challenged by the high number of lipids, their chemical diversity, and their dynamic range. In this work, we developed a tailored method for profiling and quantification combining (1) isotope dilutio...

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Bibliographic Details
Published in:Analytical chemistry (Washington) Vol. 90; no. 11; pp. 6494 - 6501
Main Authors: Rampler, Evelyn, Criscuolo, Angela, Zeller, Martin, El Abiead, Yasin, Schoeny, Harald, Hermann, Gerrit, Sokol, Elena, Cook, Ken, Peake, David A, Delanghe, Bernard, Koellensperger, Gunda
Format: Journal Article
Language:English
Published: United States American Chemical Society 05-06-2018
Subjects:
Blood plasma
Carbon 13
Carbon Isotopes - analysis
Carbon Isotopes - blood
Chemistry
Chromatography, Reverse-Phase - methods
Dilution
Humans
Identification methods
Indicator Dilution Techniques
Isotopes
Labeling
Linearity
Lipids
Lipids - analysis
Lipids - blood
Mass Spectrometry - methods
Organic chemistry
Pichia pastoris
Plasma
Workflow
Yeast
Yeasts - chemistry
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Summary:Lipid identification and quantification are essential objectives in comprehensive lipidomics studies challenged by the high number of lipids, their chemical diversity, and their dynamic range. In this work, we developed a tailored method for profiling and quantification combining (1) isotope dilution, (2) enhanced isomer separation by C30 fused-core reversed-phase material, and (3) parallel Orbitrap and ion trap detection by the Orbitrap Fusion Lumos Tribid mass spectrometer. The combination of parallelizable ion analysis without time loss together with different fragmentation techniques (HCD/CID) and an inclusion list led to higher quality in lipid identifications exemplified in human plasma and yeast samples. Moreover, we used lipidome isotope-labeling of yeast (LILY)a fast and efficient in vivo labeling strategy in Pichia pastoristo produce (nonradioactive) isotopically labeled eukaryotic lipid standards in yeast. We integrated the 13C lipids in the LC-MS workflow to enable relative and absolute compound-specific quantification in yeast and human plasma samples by isotope dilution. Label-free and compound-specific quantification was validated by comparison against a recent international interlaboratory study on human plasma SRM 1950. In this way, we were able to prove that LILY enabled quantification leads to accurate results, even in complex matrices. Excellent analytical figures of merit with enhanced trueness, precision and linearity over 4–5 orders of magnitude were observed applying compound-specific quantification with 13C-labeled lipids. We strongly believe that lipidomics studies will benefit from incorporating isotope dilution and LC-MSn strategies.
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ISSN:0003-2700
1520-6882
DOI:10.1021/acs.analchem.7b05382