New Developments in Capillary Ion Chromatography using 4 μm Columns and Charge Detection
Technical notes | 2016 | Thermo Fisher ScientificInstrumentation
Capillary ion chromatography (IC) offers critical improvements over traditional IC approaches, including enhanced mass sensitivity, superior separation efficiency, reduced sample and eluent consumption, and improved compatibility with mass spectrometry. The application of 4 µm particle-size columns under high pressure further accelerates analysis times and increases resolution for complex ionic mixtures.
This study evaluates a compact, integrated high-pressure capillary IC system featuring 4 µm-particle-size columns and reagent-free eluent generation. Key aims include demonstrating fast separations of biogenic amines and inorganic ions, high-resolution analysis of organic acids and anions, and comparing suppressed conductivity detection with novel charge detection to extend detection capabilities.
Sample Preparation
Chromatographic Conditions
Thermo Scientific™ Dionex™ ICS-4000 Capillary HPIC system composed of:
Fast cation and amine separations were completed in under 9 minutes with baseline resolution, doubling flow rates and applying steep gradients. High-resolution separations of inorganic anions and organic acids used 4 µm anion-exchange columns with suppressed conductivity and charge detection in series. In orange juice analysis, the charge detector revealed additional weakly dissociated organic acids and multi-charged species with enhanced signal intensity compared to conductivity detection alone.
Further development of multidimensional IC workflows combining standard-bore and capillary columns is anticipated to achieve ppt-level detection with minimal sample volumes. Integration of charge detection with advanced mass spectrometric methods will expand applications in metabolomics and proteomics. Ongoing miniaturization and automation will support in-field and point-of-care ion analysis.
High-pressure capillary IC using 4 µm particle-size columns significantly enhances separation speed and resolution while minimizing sample and eluent requirements. The addition of charge detection provides a universal, sensitive detection mode that complements suppressed conductivity, offering robust quantitative analysis of a broad range of ionic species.
Consumables, Ion chromatography, LC columns
IndustriesManufacturerThermo Fisher Scientific
Summary
Significance of the Topic
Capillary ion chromatography (IC) offers critical improvements over traditional IC approaches, including enhanced mass sensitivity, superior separation efficiency, reduced sample and eluent consumption, and improved compatibility with mass spectrometry. The application of 4 µm particle-size columns under high pressure further accelerates analysis times and increases resolution for complex ionic mixtures.
Objectives and Study Overview
This study evaluates a compact, integrated high-pressure capillary IC system featuring 4 µm-particle-size columns and reagent-free eluent generation. Key aims include demonstrating fast separations of biogenic amines and inorganic ions, high-resolution analysis of organic acids and anions, and comparing suppressed conductivity detection with novel charge detection to extend detection capabilities.
Methodology
Sample Preparation
- Dilution of samples followed by filtration through 0.45 µm nylon membranes.
Chromatographic Conditions
- Use of electrolytically generated hydroxide or methanesulfonic acid eluents in gradient or isocratic modes.
- Flow rates between 10 and 20 µL/min, injection volumes of 0.4 µL.
- Operation at pressures up to 34 MPa enabling use of 4 µm columns for fast or high-resolution separations.
Used Instrumentation
Thermo Scientific™ Dionex™ ICS-4000 Capillary HPIC system composed of:
- High-pressure non-metallic capillary pump.
- Reagent-Free™ IC Eluent Generator module for continuous eluent supply.
- IC Cube housing the 0.4 µL injection valve and capillary flow path.
- Electrolytic suppressor modules for conductivity detection.
- Charge detector installed downstream of conductivity suppressor for universal ionic response.
- Dionex AS-AP autosampler and Chromeleon™ 6.8 software for control and data analysis.
Main Results and Discussion
Fast cation and amine separations were completed in under 9 minutes with baseline resolution, doubling flow rates and applying steep gradients. High-resolution separations of inorganic anions and organic acids used 4 µm anion-exchange columns with suppressed conductivity and charge detection in series. In orange juice analysis, the charge detector revealed additional weakly dissociated organic acids and multi-charged species with enhanced signal intensity compared to conductivity detection alone.
Benefits and Practical Applications
- Rapid high-sensitivity analysis of trace inorganic and organic ions in environmental, food, and biological samples.
- Sub-ng detection limits for cations using capillary flow rates compatible with mass spectrometers.
- Universal response from charge detection allows quantitative comparison across mono-, di-, and tri-valent ions.
- Low eluent consumption (<0.5 L/month) and reduced waste generation enable continuous operation with minimal maintenance.
Future Trends and Opportunities
Further development of multidimensional IC workflows combining standard-bore and capillary columns is anticipated to achieve ppt-level detection with minimal sample volumes. Integration of charge detection with advanced mass spectrometric methods will expand applications in metabolomics and proteomics. Ongoing miniaturization and automation will support in-field and point-of-care ion analysis.
Conclusion
High-pressure capillary IC using 4 µm particle-size columns significantly enhances separation speed and resolution while minimizing sample and eluent requirements. The addition of charge detection provides a universal, sensitive detection mode that complements suppressed conductivity, offering robust quantitative analysis of a broad range of ionic species.
References
- Thermo Scientific Dionex ICS-4000 with Charge Detection Application Note, Thermo Fisher Scientific, 2016.
- Dionex Application Note 143 Determination of Organic Acids in Fruit Juices.
- Thermo Scientific Dionex IonPac CS19-4µm Cation-Exchange Column Product Information, Thermo Fisher Scientific.
- Thermo Scientific Dionex IonPac AS11-HC Hydroxide-Selective Anion-Exchange Column Product Information, Thermo Fisher Scientific.
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