Identification and Quantification at ppb Levels of Common Cations and Amines by IC-MS
Applications | 2016 | Thermo Fisher ScientificInstrumentation
The trace-level determination of common cations and small amines is critical in environmental monitoring, industrial process control, and quality assurance of water and beverage products. High sensitivity and specificity are required to detect contaminants at part-per-billion (ppb) levels and to confirm their identities in complex matrices. Combining ion chromatography (IC) with mass spectrometric (MS) detection addresses these needs by providing robust separation, low detection limits, and structural confirmation.
This study demonstrates an analytical method for the simultaneous identification and quantification of six inorganic cations (Li+, Na+, NH4+, K+, Mg2+, Ca2+) and four amines (ethanolamine, diethanolamine, triethanolamine, trimethylamine) at ppb levels. The method employs suppressed‐conductivity IC for separation and uses selected ion monitoring (SIM) on a single‐quadrupole MS for sensitive quantification and compound confirmation via characteristic adduct patterns.
The separation was achieved on a cation‐exchange column using isocratic 33 mM methanesulfonic acid as eluent at 0.5 mL/min and 30 °C. Post‐column, an electrolytic suppressor converted the mobile phase to nearly deionized water, compatible with electrospray ionization. A desolvation stream of isopropanol was added prior to MS to improve droplet evaporation and promote in‐source adduct formation.
Calibration standards ranged from 1 ppb to 200 ppb, depending on the analyte, using selected ion monitoring for quantification. Signal‐to‐noise and reproducibility criteria determined the lower limit of quantitation (LLOQ) and detection (MDL).
All analytes yielded linear or polynomial calibration curves with coefficients of determination (r2) above 0.998. Method detection limits were typically below 1 ppb, except for ammonium and calcium (MDL ~3–4 ppb) due to background leaching. Reproducibility, expressed as RSD for seven replicates of a 2 ppb standard, was within 12% for all compounds.
This IC‐MS method delivers reliable, sensitive detection of trace cations and amines in environmental and commercial samples. Key advantages include:
Advances in mass resolution and data processing are expected to further enhance sensitivity and reduce matrix interferences. Potential developments include:
The combined IC‐MS approach provides a powerful tool for trace‐level determination of inorganic cations and amines. It achieves low ppb detection limits, high reproducibility, and reliable confirmation through characteristic adduct formation. The method is well suited for environmental monitoring, quality control in beverage production, and other applications requiring high analytical confidence.
1. Thermo Scientific Application Note 269: Identification and Quantification at ppb Levels of Common Cations and Amines by IC‐MS, 2016.
2. Ultra Scientific and Sigma‐Aldrich product catalogs for cation and amine standards.
IC-MS
IndustriesEnergy & Chemicals
ManufacturerThermo Fisher Scientific
Summary
Significance of the Topic
The trace-level determination of common cations and small amines is critical in environmental monitoring, industrial process control, and quality assurance of water and beverage products. High sensitivity and specificity are required to detect contaminants at part-per-billion (ppb) levels and to confirm their identities in complex matrices. Combining ion chromatography (IC) with mass spectrometric (MS) detection addresses these needs by providing robust separation, low detection limits, and structural confirmation.
Objectives and Study Overview
This study demonstrates an analytical method for the simultaneous identification and quantification of six inorganic cations (Li+, Na+, NH4+, K+, Mg2+, Ca2+) and four amines (ethanolamine, diethanolamine, triethanolamine, trimethylamine) at ppb levels. The method employs suppressed‐conductivity IC for separation and uses selected ion monitoring (SIM) on a single‐quadrupole MS for sensitive quantification and compound confirmation via characteristic adduct patterns.
Methodology and Instrumentation
The separation was achieved on a cation‐exchange column using isocratic 33 mM methanesulfonic acid as eluent at 0.5 mL/min and 30 °C. Post‐column, an electrolytic suppressor converted the mobile phase to nearly deionized water, compatible with electrospray ionization. A desolvation stream of isopropanol was added prior to MS to improve droplet evaporation and promote in‐source adduct formation.
- IC System: Dionex ICS‐2000/ICS‐2100 with RFIC technology and CS12A column with guard.
- Mass Spectrometer: Thermo Scientific MSQ Plus single quadrupole with electrospray ionization in positive mode (ESI+).
- Data System: Chromeleon CDS v6.8 for instrument control, acquisition, processing, and reporting.
Calibration standards ranged from 1 ppb to 200 ppb, depending on the analyte, using selected ion monitoring for quantification. Signal‐to‐noise and reproducibility criteria determined the lower limit of quantitation (LLOQ) and detection (MDL).
Main Results and Discussion
All analytes yielded linear or polynomial calibration curves with coefficients of determination (r2) above 0.998. Method detection limits were typically below 1 ppb, except for ammonium and calcium (MDL ~3–4 ppb) due to background leaching. Reproducibility, expressed as RSD for seven replicates of a 2 ppb standard, was within 12% for all compounds.
- SIM enabled resolution of co‐eluting species by m/z, allowing accurate quantification despite chromatographic overlap.
- Isopropanol significantly improved adduct formation and spectral cleanliness compared to methanol and acetonitrile.
- Application to real water and beverage samples demonstrated robust detection of target ions at sub‐mg/L levels after appropriate dilution.
Practical Benefits and Applications
This IC‐MS method delivers reliable, sensitive detection of trace cations and amines in environmental and commercial samples. Key advantages include:
- Low maintenance, affordable single‐quadrupole MS detector optimized for low mass range.
- High selectivity via SIM and confirmatory full‐scan spectra for compound verification.
- Compatibility with complex matrices through electrolytic suppression and organic solvent mixing.
Future Trends and Opportunities
Advances in mass resolution and data processing are expected to further enhance sensitivity and reduce matrix interferences. Potential developments include:
- Integration of high‐resolution MS for greater mass accuracy and expanded compound screening.
- Automated suppressor and reagent management to improve uptime and reproducibility.
- Application expansion to broader classes of ionic species, including organic acids and small peptides.
Conclusion
The combined IC‐MS approach provides a powerful tool for trace‐level determination of inorganic cations and amines. It achieves low ppb detection limits, high reproducibility, and reliable confirmation through characteristic adduct formation. The method is well suited for environmental monitoring, quality control in beverage production, and other applications requiring high analytical confidence.
References
1. Thermo Scientific Application Note 269: Identification and Quantification at ppb Levels of Common Cations and Amines by IC‐MS, 2016.
2. Ultra Scientific and Sigma‐Aldrich product catalogs for cation and amine standards.
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