Performance Verification of a Proposed USP Monograph for Sorbitan Monooleate Using a Gel Permeation Chromatography (GPC) Method With Refractive Index (RI) Detection
Applications | 2024 | WatersInstrumentation
Sorbitan monooleate (Span 80) is a widely used nonionic surfactant that stabilizes emulsions in pharmaceuticals, cosmetics and food products.
Updating monographs ensures consistent quality and safety of excipients, supporting regulatory compliance and robust analytical workflows.
This study evaluates the performance of a proposed USP monograph for sorbitan monooleate, employing a gel permeation chromatography (GPC) method with refractive index (RI) detection.
The research aims to verify system suitability, assay accuracy for sorbitan esters, and limits for organic impurities under revised USP criteria.
The method follows the proposed USP monograph protocols:
System suitability requirements were met, with relative standard deviations ≤0.01% for retention times and ≤0.68% for peak areas. Resolution criteria defined by the USP were achieved.
Assay results for sorbitan tri-/higher esters, diesters, and monoesters fell within acceptance ranges by area normalization. Organic impurity levels were below limit thresholds.
Advances in detector sensitivity and column technologies may further improve resolution and reduce analysis time.
Integration with automated sample preparation and high-throughput data processing can enhance laboratory efficiency.
Similar GPC-RI methods could be adapted for other nonionic surfactants and polymeric excipients.
The GPC method proposed in the USP monograph for sorbitan monooleate was successfully implemented on the Arc HPLC system with RI detection. It fulfilled all USP criteria for system suitability, assay performance, and impurity limits, offering a reliable, standardized analytical approach.
GPC/SEC
IndustriesPharma & Biopharma
ManufacturerWaters
Summary
Importance of the Topic
Sorbitan monooleate (Span 80) is a widely used nonionic surfactant that stabilizes emulsions in pharmaceuticals, cosmetics and food products.
Updating monographs ensures consistent quality and safety of excipients, supporting regulatory compliance and robust analytical workflows.
Study Objectives and Overview
This study evaluates the performance of a proposed USP monograph for sorbitan monooleate, employing a gel permeation chromatography (GPC) method with refractive index (RI) detection.
The research aims to verify system suitability, assay accuracy for sorbitan esters, and limits for organic impurities under revised USP criteria.
Used Instrumentation
- Arc HPLC System equipped with quaternary solvent manager, flow-through needle sample manager, and strong solvent compatibility kit
- 2414 Refractive Index Detector (flow cell temperature 30 °C, sampling rate 10 pts/s)
- Empower 3 chromatography data software for acquisition and analysis
Methodology
The method follows the proposed USP monograph protocols:
- Mobile phase: tetrahydrofuran (THF), isocratic flow at 0.9 mL/min
- Column assembly: two Styragel columns (HR 1, 100 Å; HR 0.5, 50 Å) in series at 30 °C
- Sample and standard solutions prepared in THF at 1.0 mg/mL
- Injection volume: 20 µL; total run time: 30 min
- System suitability tested with six replicate injections, evaluating retention time and peak area reproducibility
Key Results and Discussion
System suitability requirements were met, with relative standard deviations ≤0.01% for retention times and ≤0.68% for peak areas. Resolution criteria defined by the USP were achieved.
Assay results for sorbitan tri-/higher esters, diesters, and monoesters fell within acceptance ranges by area normalization. Organic impurity levels were below limit thresholds.
Benefits and Practical Applications
- Validated GPC method ensures accurate quantification of sorbitan ester profiles and impurity levels
- The strong solvent compatibility kit extends system durability when using THF
- Provides a standardized protocol for regulatory quality control in excipient manufacturing
Future Trends and Potential Applications
Advances in detector sensitivity and column technologies may further improve resolution and reduce analysis time.
Integration with automated sample preparation and high-throughput data processing can enhance laboratory efficiency.
Similar GPC-RI methods could be adapted for other nonionic surfactants and polymeric excipients.
Conclusion
The GPC method proposed in the USP monograph for sorbitan monooleate was successfully implemented on the Arc HPLC system with RI detection. It fulfilled all USP criteria for system suitability, assay performance, and impurity limits, offering a reliable, standardized analytical approach.
References
- United States Pharmacopeia proposed revision to monograph for sorbitan monooleate, USP-PF 50(2)
- Technical literature on sorbitan monooleate applications and properties
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