Rapid Optimization of MRM-MS Instrument Parameters by Subtle Alteration of Precursor and Product <i>m</i>/<i>z</i> Targets

Sherwood, Carly A.; Eastham, Ashley; Lee, Lik Wee; Risler, Jenni; Mirzaei, Hamid; Falkner, Jayson A.; Martin, Daniel

doi:10.1021/pr801122b

Cited by 69 publications

(64 citation statements)

References 23 publications

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“…Software algorithms have been developed for optimization of instrumental parameters and to search for putative posttranslational-modified sites in a target protein, which further extends the application of this technique [35][36][37][38]. Thus, multiplexed MRM-MS assays offer an attractive alternative to ELISA through the development of a comprehensive panel of biomarkers.…”

Section: Introductionmentioning

confidence: 99%

Multiplexed quantification of 63 proteins in human urine by multiple reaction monitoring-based mass spectrometry for discovery of potential bladder cancer biomarkers

Chen

Domański

et al. 2012

Journal of Proteomics

134

124

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Section: Introductionmentioning

confidence: 99%

Multiplexed quantification of 63 proteins in human urine by multiple reaction monitoring-based mass spectrometry for discovery of potential bladder cancer biomarkers

Chen

Domański

et al. 2012

Journal of Proteomics

134

124

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“…Briefly, after proteins were loaded onto a 10-kDa filter unit (Pall, were quantified by the median of the transformed reporter ion intensity ratios [38,39] . to select the most intense transitions for the targeted peptides [40,41] . The b and y ions of …”

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confidence: 99%

Early urinary candidate biomarker discovery in a rat thioacetamide-induced liver fibrosis model

Zhang

Yuan

et al. 2017

Preprint

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Biomarker is the change associated with the disease. Blood is relatively stable because of the homeostatic mechanisms of the body. However, urine accumulates changes of the body, which makes it a better early biomarker source. Liver fibrosis, which results from the deposition of extracellular matrix (ECM) components, is a reversible pathological condition, whereas cirrhosis, the end-stage of liver fibrosis, is irreversible. Consequently, noninvasive early biomarkers for fibrosis are desperately needed. In this study, differential urinary proteins were identified in the thioacetamide (TAA) liver fibrosis rat model using tandem mass tagging and two-dimensional liquid chromatography tandem mass spectrometry (2DLC-MS/MS). A total of 766 urinary proteins were identified, 143 and 118 of which were significantly changed in the TAA 1-week and 3-week groups, respectively. Multiple reaction monitoring (MRM)-targeted proteomics was used to further validate the abundant differentially expressed proteins in the TAA 1-week, 3-week, 6-week and 8-week groups. A total of 40 urinary proteins were statistically significant (fold change >2 and p<0.05), 15 of which had been previously reported as biomarkers of liver fibrosis, cirrhosis or other related diseases and 10 of which had been reported to be associated with the pathology and mechanism of liver fibrosis. These differential proteins were detected in urine before the alanine aminotransferase (ALT) and aspartate transaminase (AST) changes in the serum and before fibrosis was observed upon hematoxylin and eosin (HE) and Masson’s staining.

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“…It has recently been proved that an increase in the number of analytes detected can be achieved by using the time-segmented or scheduled MRM approach [97,98], which decreases the number of concurrent ion transitions monitored per time-scale (by splitting an LC run into separate time windows based on analytes' retention times and monitoring a few particular transitions eluted only within the individual time segments), and thus enables both dwell time (sensitivity) and data-points (peak profile and ruggedness) to remain optimal for higher levels of MRM multiplexing. Furthermore, to overcome several drawbacks associated with the classical time-segmented data acquisition mode (including time segments boundaries, tedious manual method development and acquisition limitations), the use of some advanced software packages, such as the so-called scheduled MRM algorithm (sMRM), dynamic MRM and MRMaid, shows promise in the automation to assist transition design and optimization [98][99][100]. The algorithms offered by different vendors enable intelligent use of retention time and dynamic time-window plus a defined cycle time to simplify development of LC-MRM assays for multi-target (e.g., 700 drugs [101]) screening…”

Section: Current Methodologies In Lc-mrm-based Metabolite Profiling 4mentioning

confidence: 99%

Liquid Chromatography-Mass Spectrometric Multiple Reaction Monitoring-based Strategies for Expanding Targeted Profiling towards Quantitative Metabolomics

Guo

Chen²,

Liu³

et al. 2012

CDM

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Recent advances in analytical methodologies have made it possible to bring metabolomic profiling into quantitative metabolomics that permits precise measurements of comprehensive small-molecule profiles. Modern liquid chromatography-tandem mass spectrometry (LC-MS/MS) with multiple reaction monitoring (MRM) mode serves as the foundation for accurate simultaneous multi-analyte quantitation across large sample sets to provide high-quality information on target molecular profiles in complex systems. Despite the intrinsic multiplexing potential of the LC-MRM-MS technique, the key bottleneck in current LC-MRM-based assays is generally the limited analyte coverage and throughput capacity. Nowadays, the MRM-based approach has emerged as an attractive strategy for quantitative proteomic analysis and high-throughput biomarker discovery. So far, the full potential of the contemporary LCMRM methodology unleashed for quantitative metabolite profiling and metabolomic measurements of non-peptidic small molecules is rarely discussed. In this review we attempt to provide an overview on the major recent developments in LC-MRM-based strategies for quantitative profiling of multi- and non-target small molecules in biological samples. This article highlights the utility and power of the LC-MRM-based targeted approaches as valuable bioanalytical tools for low-cost, multiplexed quantitation on a large scale, with special emphasis on the promise of combining various strategies for expanding coverage and throughput of the LC-MRM-based assays to cover the gap between a widely targeted profiling and large-scale unknown screening towards comparative or quantitative metabolomics. General issues raised in metabolite profiling, such as basic aspects of bioanalysis, methodological dilemmas and challenges in quantitative metabolomics are addressed, and different strategies to circumvent the existing bottleneck and potential pitfalls of the current LC-MRM-MS techniques are outlined. In addition, the rudiments of LC-MRM-MS and its recent applications in combination with such strategies for biomarker quantitation and verification is also described.

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Rapid Optimization of MRM-MS Instrument Parameters by Subtle Alteration of Precursor and Product m/z Targets

Cited by 69 publications

References 23 publications

Multiplexed quantification of 63 proteins in human urine by multiple reaction monitoring-based mass spectrometry for discovery of potential bladder cancer biomarkers

Multiplexed quantification of 63 proteins in human urine by multiple reaction monitoring-based mass spectrometry for discovery of potential bladder cancer biomarkers

Early urinary candidate biomarker discovery in a rat thioacetamide-induced liver fibrosis model

Liquid Chromatography-Mass Spectrometric Multiple Reaction Monitoring-based Strategies for Expanding Targeted Profiling towards Quantitative Metabolomics

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