Ion Chromatography for Pharmaceutical Analysis
Presentations | 2016 | Thermo Fisher Scientific | AAPSInstrumentation
Ion chromatography (IC) has emerged as a critical tool for pharmaceutical analysis by enabling sensitive, direct detection of ionic and polar drug substances and impurities. Its high automation, minimal solvent consumption and compatibility with non-chromophoric analytes make IC a preferred technique for quality control and method modernization in both drug substance and drug product assays.
This work introduces the fundamentals of IC, highlights two representative pharmaceutical applications, and outlines a systematic approach to IC method development. Examples include anion and cation assays aligned with pharmacopeial monographs and a case study on aminoglycoside antibiotics.
IC combines ion-exchange separation with chemically suppressed conductivity detection or pulsed amperometric detection (PAD). Hydroxide eluents are generated on-line using EluGen cartridges and eluent generators (EG50, EGC 500) to deliver reproducible KOH or methanesulfonic acid gradients. Columns such as Dionex IonPac AS18/AG18 for anions, CG12A/CS12A or CS16 for cations, and CarboPac MA1 for carbohydrates enable high-capacity separations. Suppressors (AERS 500, CERS 500, SC-CSRS ULTRA) remove background conductivity. PAD on gold electrodes facilitates direct analysis of carbohydrates and aminoglycosides. Instrument platforms include the Thermo Scientific™ Dionex™ ICS-5000 series.
• Anion separations resolved fluoride to phosphate and trifluoroacetate in under 20 minutes using a KOH gradient on AS18.
• Cation separations of lithium to calcium were achieved on CS12A or CS16 with methanesulfonic acid gradients and suppressed conductivity.
• A USP-proposed method for sodium nitrite monograph replaced permanganate titration by IC assay of nitrite and nitrate with K2CO3/KHCO3 eluent.
• Lithium hydroxide and its calcium impurity were quantified at pharmacopeial limits using CS16 and CERS 500 detection.
• Kanamycin B and amikacin assays employed HPAE-PAD on CarboPac MA1 with 115 mM NaOH, yielding baseline resolution and direct quantification in drug substances and products.
IC is poised for broader adoption in pharmaceutical R&D and QC through integration with mass spectrometry, development of miniaturized and high-throughput formats, and novel suppressor technologies. Further automation of method scouting, data processing and compliance workflows will streamline regulatory submissions. Expansion into biopharmaceuticals and complex formulations will drive new column chemistries and detection schemes.
Ion chromatography offers a versatile, robust platform for pharmaceutical assays, impurity profiling and counter-ion analysis. Its automation, sensitivity and green credentials support ongoing modernization of pharmacopeial methods and emerging analytical challenges in drug development.
No explicit references were provided in the source document.
Ion chromatography
IndustriesPharma & Biopharma
ManufacturerThermo Fisher Scientific
Summary
Significance of the Topic
Ion chromatography (IC) has emerged as a critical tool for pharmaceutical analysis by enabling sensitive, direct detection of ionic and polar drug substances and impurities. Its high automation, minimal solvent consumption and compatibility with non-chromophoric analytes make IC a preferred technique for quality control and method modernization in both drug substance and drug product assays.
Objectives and Overview of the Study
This work introduces the fundamentals of IC, highlights two representative pharmaceutical applications, and outlines a systematic approach to IC method development. Examples include anion and cation assays aligned with pharmacopeial monographs and a case study on aminoglycoside antibiotics.
Methodology and Instrumentation
IC combines ion-exchange separation with chemically suppressed conductivity detection or pulsed amperometric detection (PAD). Hydroxide eluents are generated on-line using EluGen cartridges and eluent generators (EG50, EGC 500) to deliver reproducible KOH or methanesulfonic acid gradients. Columns such as Dionex IonPac AS18/AG18 for anions, CG12A/CS12A or CS16 for cations, and CarboPac MA1 for carbohydrates enable high-capacity separations. Suppressors (AERS 500, CERS 500, SC-CSRS ULTRA) remove background conductivity. PAD on gold electrodes facilitates direct analysis of carbohydrates and aminoglycosides. Instrument platforms include the Thermo Scientific™ Dionex™ ICS-5000 series.
Main Results and Discussion
• Anion separations resolved fluoride to phosphate and trifluoroacetate in under 20 minutes using a KOH gradient on AS18.
• Cation separations of lithium to calcium were achieved on CS12A or CS16 with methanesulfonic acid gradients and suppressed conductivity.
• A USP-proposed method for sodium nitrite monograph replaced permanganate titration by IC assay of nitrite and nitrate with K2CO3/KHCO3 eluent.
• Lithium hydroxide and its calcium impurity were quantified at pharmacopeial limits using CS16 and CERS 500 detection.
• Kanamycin B and amikacin assays employed HPAE-PAD on CarboPac MA1 with 115 mM NaOH, yielding baseline resolution and direct quantification in drug substances and products.
Benefits and Practical Applications
- Direct, non-derivatized analysis of ions and polar compounds.
- Enhanced automation and throughput relative to conventional HPLC and titrations.
- Elimination of organic solvents supports green chemistry initiatives.
- Reliable counter-ion identification for salt form APIs.
- Compatibility with official pharmacopeial methods and modernization efforts.
Future Trends and Opportunities
IC is poised for broader adoption in pharmaceutical R&D and QC through integration with mass spectrometry, development of miniaturized and high-throughput formats, and novel suppressor technologies. Further automation of method scouting, data processing and compliance workflows will streamline regulatory submissions. Expansion into biopharmaceuticals and complex formulations will drive new column chemistries and detection schemes.
Conclusion
Ion chromatography offers a versatile, robust platform for pharmaceutical assays, impurity profiling and counter-ion analysis. Its automation, sensitivity and green credentials support ongoing modernization of pharmacopeial methods and emerging analytical challenges in drug development.
References
No explicit references were provided in the source document.
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