Analysis of Residual Solvents in Pharmaceuticals
Applications | 2022 | ShimadzuInstrumentation
Residual solvents from manufacturing processes can pose health risks and affect drug stability. Regulatory guidelines classify solvents by toxicity and set strict limits to ensure patient safety and product quality.
This application note demonstrates a gas chromatography method with flame ionization detection (GC-FID) for simultaneous quantification of 13 Class 2 residual solvents in water-soluble pharmaceutical samples. The goal is to achieve baseline separation, reliable quantitation, and compliance with international standards.
Key components and parameters:
The method resolved 13 solvents including ethylbenzene, xylenes, nitromethane, and N,N-dimethylformamide within a single analysis. Retention times were reproducible, and peak shapes were well defined, supporting quantitation down to regulatory limits. A long final hold at 220 °C ensured elution of high-boiling analytes.
This protocol provides a robust, high-throughput tool for pharmaceutical QC laboratories. It enables accurate monitoring of multiple Class 2 solvents in diverse water-soluble formulations, ensuring adherence to ICH Q3C guidelines.
Ongoing developments may include faster column chemistries, automation for sample preparation, and coupling with mass spectrometry to extend detection capabilities to Class 1 and Class 3 solvents.
The SH-PolarWax GC-FID method on Shimadzu Nexis GC-2030 offers reproducible separation and quantitation of key residual solvents, supporting pharmaceutical safety and regulatory compliance.
GC, GC columns, Consumables
IndustriesPharma & Biopharma
ManufacturerShimadzu
Summary
Importance of Residual Solvent Analysis in Pharmaceuticals
Residual solvents from manufacturing processes can pose health risks and affect drug stability. Regulatory guidelines classify solvents by toxicity and set strict limits to ensure patient safety and product quality.
Objectives and Overview of the Study
This application note demonstrates a gas chromatography method with flame ionization detection (GC-FID) for simultaneous quantification of 13 Class 2 residual solvents in water-soluble pharmaceutical samples. The goal is to achieve baseline separation, reliable quantitation, and compliance with international standards.
Methodology and Instrumentation Used
Key components and parameters:
- GC System: Nexis™ GC-2030 with AOC-20i Plus autosampler
- Column: SH-PolarWax, 30 m × 0.53 mm I.D., 1 μm film thickness
- Carrier Gas: Helium in constant pressure mode (26.6 kPa)
- Injection: High-pressure split (1:1) at 160 °C, 1 μL sample volume
- Oven Program: 50 °C hold (7 min), 4 °C/min to 110 °C, then 10 °C/min to 220 °C (20 min), total run ~53 min
- Detector: FID at 240 °C with H₂ (32 mL/min), air (200 mL/min), and He makeup (24 mL/min)
Key Results and Discussion
The method resolved 13 solvents including ethylbenzene, xylenes, nitromethane, and N,N-dimethylformamide within a single analysis. Retention times were reproducible, and peak shapes were well defined, supporting quantitation down to regulatory limits. A long final hold at 220 °C ensured elution of high-boiling analytes.
Benefits and Practical Applications
This protocol provides a robust, high-throughput tool for pharmaceutical QC laboratories. It enables accurate monitoring of multiple Class 2 solvents in diverse water-soluble formulations, ensuring adherence to ICH Q3C guidelines.
Future Trends and Potential Applications
Ongoing developments may include faster column chemistries, automation for sample preparation, and coupling with mass spectrometry to extend detection capabilities to Class 1 and Class 3 solvents.
Conclusion
The SH-PolarWax GC-FID method on Shimadzu Nexis GC-2030 offers reproducible separation and quantitation of key residual solvents, supporting pharmaceutical safety and regulatory compliance.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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