Multicomponent Analysis of Metabolites in Human Plasma using GC-MS/MS
Applications | 2015 | ShimadzuInstrumentation
Profiling metabolites in human plasma is critical for biomarker discovery, clinical diagnostics, and understanding disease mechanisms. High-confidence quantification of a broad range of metabolites supports both fundamental research and clinical studies, driving personalized medicine and quality control in pharmaceutical development.
This study evaluates a triple quadrupole GC-MS/MS method in multiple reaction monitoring (MRM) mode for simultaneous analysis of hundreds of metabolites in human plasma. The goals are to compare traditional scan mode with MRM for sensitivity and selectivity, and to demonstrate comprehensive metabolite coverage using a smart metabolite database.
Sample Preparation:
Instrumental Setup:
MRM measurement yielded a total ion chromatogram showing clear, well-resolved peaks for plasma metabolites. Compared to scan mode, MRM dramatically reduced background interferences and enhanced sensitivity, enabling detection of low-abundance compounds that were obscured in scan traces. From 475 potential targets in the database, 221 TMS-derivatized metabolites were unambiguously quantified in standard human plasma, demonstrating broad coverage across amino acids, organic acids, sugars, fatty acids, and nucleotides.
Expansion of MRM libraries will cover additional metabolite classes, including lipids and xenobiotics. Integrating automated sample preparation and data processing pipelines will enable large-scale clinical studies. Coupling targeted MRM with high-resolution full scan methods may provide complementary qualitative and quantitative insights, advancing systems biology and personalized diagnostics.
The triple quadrupole GC-MS/MS MRM approach offers robust, sensitive, and selective analysis of a wide spectrum of plasma metabolites. It outperforms conventional scan methods by delivering accurate quantification with minimal interference. This platform is well suited for biomarker discovery, clinical chemistry, and quality control applications.
Nishiumi S., Shinohara M., Ikeda A., et al. Metabolomics 6 (2010) 518–528.
GC/MSD, GC/MS/MS, GC/QQQ
IndustriesMetabolomics, Clinical Research
ManufacturerShimadzu
Summary
Significance of the Topic
Profiling metabolites in human plasma is critical for biomarker discovery, clinical diagnostics, and understanding disease mechanisms. High-confidence quantification of a broad range of metabolites supports both fundamental research and clinical studies, driving personalized medicine and quality control in pharmaceutical development.
Study Objectives and Overview
This study evaluates a triple quadrupole GC-MS/MS method in multiple reaction monitoring (MRM) mode for simultaneous analysis of hundreds of metabolites in human plasma. The goals are to compare traditional scan mode with MRM for sensitivity and selectivity, and to demonstrate comprehensive metabolite coverage using a smart metabolite database.
Methodology and Instrumentation
Sample Preparation:
- 50 µL standard human plasma spiked with 2-isopropylmalic acid as an internal standard.
- Metabolites extracted by methanol/water/chloroform (2.5:1:1).
- Derivatization via methoximation followed by trimethylsilylation (TMS).
Instrumental Setup:
- GC-MS/MS system: GCMS-TQ8040 with triple quadrupole.
- Column: BPX-5 (30 m × 0.25 mm I.D., 0.25 µm film).
- Injection: Split mode, 1 µL, 250 °C injector.
- Oven program: 60 °C (2 min) → 330 °C at 15 °C/min (3 min hold).
- Interface 280 °C, ion source 200 °C.
- Carrier gas linear velocity 39 cm/s.
- Detection modes: Scan (m/z 45–600) and MRM (custom transitions from Smart Metabolites Database).
Main Results and Discussion
MRM measurement yielded a total ion chromatogram showing clear, well-resolved peaks for plasma metabolites. Compared to scan mode, MRM dramatically reduced background interferences and enhanced sensitivity, enabling detection of low-abundance compounds that were obscured in scan traces. From 475 potential targets in the database, 221 TMS-derivatized metabolites were unambiguously quantified in standard human plasma, demonstrating broad coverage across amino acids, organic acids, sugars, fatty acids, and nucleotides.
Benefits and Practical Applications
- Improved selectivity: Dual mass filtering in Q1 and Q3 removes coeluting interferences.
- Higher sensitivity: MRM transitions deliver low detection limits for trace metabolites.
- Quantitative accuracy: Stable internal standard corrects for extraction and derivatization variability.
- High throughput: Simultaneous monitoring of hundreds of metabolites accelerates metabolomic profiling in clinical and research settings.
Future Trends and Applications
Expansion of MRM libraries will cover additional metabolite classes, including lipids and xenobiotics. Integrating automated sample preparation and data processing pipelines will enable large-scale clinical studies. Coupling targeted MRM with high-resolution full scan methods may provide complementary qualitative and quantitative insights, advancing systems biology and personalized diagnostics.
Conclusion
The triple quadrupole GC-MS/MS MRM approach offers robust, sensitive, and selective analysis of a wide spectrum of plasma metabolites. It outperforms conventional scan methods by delivering accurate quantification with minimal interference. This platform is well suited for biomarker discovery, clinical chemistry, and quality control applications.
Reference
Nishiumi S., Shinohara M., Ikeda A., et al. Metabolomics 6 (2010) 518–528.
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