CHRONECT Workstation MCPD
Brochures and specifications | 2018 | Axel SemrauInstrumentation
Refinement of edible oils and fats at elevated temperatures can generate toxic contaminants such as 3-MCPD, 2-MCPD and glycidol, which are bound to fatty acid esters. Due to their potential carcinogenicity and the EFSA’s daily intake limit of 0.8 µg/kg body weight for 3-MCPD, reliable and efficient analytical workflows are essential for food safety and quality control.
This work presents a fully automated indirect GC-MS/MS method based on the DGF Fast & Clean protocol (derived from DGF C-VI 18(10)) for quantifying free MCPD and glycidol after transesterification. The primary aims were to reduce sample preparation time, increase throughput, and maintain compliance with established reference methods.
The procedure involves transesterification of oil samples in the presence of chloride salts to release bound MCPD and glycidol. Following alkaline transesterification, the free analytes are extracted, derivatized, cleaned, and finally measured by GC-MS/MS. The DGF Fast & Clean approach streamlines multiple reaction steps into a 45-minute automated sequence compared to conventional 18-hour protocols.
The automated workstation achieved full sample turnaround in 45 minutes, enabling up to 36 analyses per day with high precision and sensitivity. Automated blank runs and QC samples ensure accurate LOD/LOQ and recovery monitoring. Performance matches or exceeds conventional methods, eliminating manual handling and reducing contamination risk.
Further integration with alternative GC-MS platforms, expansion to direct LC-MS/MS ester profiling, and real-time data connectivity promise enhanced contamination surveillance. Modular automation may be adapted for other lipid-bound contaminants and high-throughput screening in regulatory environments.
The fully automated CHRONECT Workstation MCPD delivers a rapid, robust, and scalable solution for MCPD and glycidol analysis in fats and oils. By combining established DGF methodology with advanced robotic handling, it sets new standards for efficiency and data reliability in food safety analytics.
GC/MSD, GC/MS/MS, Sample Preparation, GC/QQQ
IndustriesFood & Agriculture
ManufacturerBruker, Axel Semrau
Summary
Significance of the Topic
Refinement of edible oils and fats at elevated temperatures can generate toxic contaminants such as 3-MCPD, 2-MCPD and glycidol, which are bound to fatty acid esters. Due to their potential carcinogenicity and the EFSA’s daily intake limit of 0.8 µg/kg body weight for 3-MCPD, reliable and efficient analytical workflows are essential for food safety and quality control.
Study Objectives and Overview
This work presents a fully automated indirect GC-MS/MS method based on the DGF Fast & Clean protocol (derived from DGF C-VI 18(10)) for quantifying free MCPD and glycidol after transesterification. The primary aims were to reduce sample preparation time, increase throughput, and maintain compliance with established reference methods.
Methodology
The procedure involves transesterification of oil samples in the presence of chloride salts to release bound MCPD and glycidol. Following alkaline transesterification, the free analytes are extracted, derivatized, cleaned, and finally measured by GC-MS/MS. The DGF Fast & Clean approach streamlines multiple reaction steps into a 45-minute automated sequence compared to conventional 18-hour protocols.
Used Instrumentation
- CHRONECT Robotic platform with CHRONOS software control
- CTC PAL3 DHR autosampler (160 cm model)
- Bruker EVOQ GC-TQ coupled with a 456-GC and Blackflush element
Key Findings and Discussion
The automated workstation achieved full sample turnaround in 45 minutes, enabling up to 36 analyses per day with high precision and sensitivity. Automated blank runs and QC samples ensure accurate LOD/LOQ and recovery monitoring. Performance matches or exceeds conventional methods, eliminating manual handling and reducing contamination risk.
Benefits and Practical Applications
- Rapid routine analysis for food laboratories and QC departments
- Compatible with multiple MCPD ester methods (DGF classical, Zwagerman-Overman, AOCS protocols)
- Minimal maintenance due to Clean-Technology design
- Expandable for additional automated workflows
Future Trends and Potential Applications
Further integration with alternative GC-MS platforms, expansion to direct LC-MS/MS ester profiling, and real-time data connectivity promise enhanced contamination surveillance. Modular automation may be adapted for other lipid-bound contaminants and high-throughput screening in regulatory environments.
Conclusion
The fully automated CHRONECT Workstation MCPD delivers a rapid, robust, and scalable solution for MCPD and glycidol analysis in fats and oils. By combining established DGF methodology with advanced robotic handling, it sets new standards for efficiency and data reliability in food safety analytics.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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