Improving the Detection of Thyroglobulin in Human Plasma for Clinical Research by Combining SISCAPA Enrichment and Microflow LC-MS
Applications | 2016 | WatersInstrumentation
Sensitive and accurate measurement of thyroglobulin (Tg) in human plasma is critical for clinical research because conventional immunoassays can yield false negatives due to anti-Tg autoantibodies. LC-MS methods with peptide immunoenrichment offer improved selectivity and quantitation at low concentration levels while consuming less sample.
This study evaluated a combined SISCAPA enrichment and microflow LC-MS approach using a dual-pump trapping ionKey/MS system. Goals included lowering the limit of quantitation (LLOQ) for Tg, reducing sample volume requirements, and maintaining accuracy, precision, and throughput relative to standard flow methods.
A calibration curve from 2,000 to 0.64 amol on column showed excellent linearity and reproducibility (CV ~16% at 13 amol). Plasma titration demonstrated linear response down to 40 µL sample. In a head-to-head comparison with standard flow (Agilent 1290/6490), the microflow method achieved R2=0.998 correlation, superior precision, and agreement within 95% confidence by Bland-Altman analysis. Reverse curve experiments indicated an LLOD of 15 amol and an LLOQ of 45 amol on-column. Spiking purified Tg in bovine plasma yielded an overall assay LLOQ of ~0.78 ng/mL using 50 µL sample.
Wider adoption of microflow LC-MS with immunoenrichment may enable multiplexed biomarker panels in clinical research, further reduction in sample and solvent consumption, and integration with automated workflows for high-throughput precision diagnostics.
The dual-pump trapping ionKey/MS system combined with SISCAPA enrichment provides a robust and sensitive platform for Tg analysis, achieving sub-ng/mL quantitation using minimal plasma volumes while preserving accuracy, enhanced precision, and efficient throughput, making it a viable solution for clinical research.
LC/MS, LC/MS/MS, LC/QQQ
IndustriesClinical Research
ManufacturerWaters
Summary
Significance of the Topic
Sensitive and accurate measurement of thyroglobulin (Tg) in human plasma is critical for clinical research because conventional immunoassays can yield false negatives due to anti-Tg autoantibodies. LC-MS methods with peptide immunoenrichment offer improved selectivity and quantitation at low concentration levels while consuming less sample.
Objectives and Study Overview
This study evaluated a combined SISCAPA enrichment and microflow LC-MS approach using a dual-pump trapping ionKey/MS system. Goals included lowering the limit of quantitation (LLOQ) for Tg, reducing sample volume requirements, and maintaining accuracy, precision, and throughput relative to standard flow methods.
Methodology and Used Instrumentation
- Sample preparation: tryptic digestion of plasma, immuno-enrichment of a signature Tg peptide (FSPDDSAGASALLR) with stable isotope-labeled standard and magnetic antibody beads.
- Chromatography and detection: ACQUITY UPLC M-Class system with dual-pump trapping; ionKey/MS coupled to Xevo TQ-S in MRM mode; iKey Peptide BEH C18 separation device; MassLynx and TargetLynx software.
- Operating conditions: 20 µL injection, 3 µL/min microflow, trap loading at 50 µL/min, total cycle time 6.75 min, sub-2 ng/mL quantitation with 50 µL plasma.
Main Results and Discussion
A calibration curve from 2,000 to 0.64 amol on column showed excellent linearity and reproducibility (CV ~16% at 13 amol). Plasma titration demonstrated linear response down to 40 µL sample. In a head-to-head comparison with standard flow (Agilent 1290/6490), the microflow method achieved R2=0.998 correlation, superior precision, and agreement within 95% confidence by Bland-Altman analysis. Reverse curve experiments indicated an LLOD of 15 amol and an LLOQ of 45 amol on-column. Spiking purified Tg in bovine plasma yielded an overall assay LLOQ of ~0.78 ng/mL using 50 µL sample.
Benefits and Practical Applications
- Quantitation below 1 ng/mL Tg with 10× less plasma than standard flow.
- Improved precision across replicates and high analytical selectivity.
- Reduced solvent consumption and smaller injection volumes.
- Cycle time comparable to standard methods with similar throughput.
Future Trends and Possibilities
Wider adoption of microflow LC-MS with immunoenrichment may enable multiplexed biomarker panels in clinical research, further reduction in sample and solvent consumption, and integration with automated workflows for high-throughput precision diagnostics.
Conclusion
The dual-pump trapping ionKey/MS system combined with SISCAPA enrichment provides a robust and sensitive platform for Tg analysis, achieving sub-ng/mL quantitation using minimal plasma volumes while preserving accuracy, enhanced precision, and efficient throughput, making it a viable solution for clinical research.
References
- Lame ME, Chambers EE. Improving a High Sensitivity Assay for the Quantification of Teriparatide in Human Plasma Using the ionKey/MS System. Waters Application Note, 720004948EN. 2015.
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