Geranium Oil (Commercial) - Rt-βDEXsa™
Applications | | RestekInstrumentation
The chiral composition of essential oils critically influences their olfactory properties and biological activities.
Enantioselective analysis enables detailed profiling of aroma compounds in applications across fragrance, flavor, and quality control.
This application note demonstrates the separation and identification of key chiral terpenes in commercial geranium oil using a cyclodextrin-based Rt-βDEXsa GC column.
The focus is on resolving enantiomers of rose oxide, linalool, and citronellol along with other monoterpenoids.
Gas chromatography with flame ionization detection was employed under controlled temperature ramping to achieve baseline separation of enantiomers.
The method achieved complete resolution of cis- and trans-rose oxide enantiomers (1a, 1b, 2a, 2b), R- and S-linalool (5a, 5b), and R- and S-citronellol (6a, 6b).
Additional components such as isomenthone, menthone, geraniol, and citronellyl formate were also well separated.
The gradual temperature ramp ensured sharp peaks and minimal coelution, facilitating accurate quantification.
The approach enables reliable enantiomeric purity assessment in fragrance formulations, ensuring consistency and authenticity.
It supports regulatory compliance and enhances research in flavor and fragrance chemistry.
Emerging chiral stationary phases and multidimensional GC techniques promise faster analysis and higher resolution.
Integration with mass spectrometry can expand detection capabilities for trace-level enantiomeric analysis.
Rt-βDEXsa GC-FID provides an effective, reproducible method for chiral separation of geranium oil constituents.
Its application enhances quality control and research in the flavor and fragrance industry.
No literature references were provided in the source document.
GC, GC columns, Consumables
IndustriesFood & Agriculture
ManufacturerRestek
Summary
Significance of the Topic
The chiral composition of essential oils critically influences their olfactory properties and biological activities.
Enantioselective analysis enables detailed profiling of aroma compounds in applications across fragrance, flavor, and quality control.
Objectives and Overview of the Study
This application note demonstrates the separation and identification of key chiral terpenes in commercial geranium oil using a cyclodextrin-based Rt-βDEXsa GC column.
The focus is on resolving enantiomers of rose oxide, linalool, and citronellol along with other monoterpenoids.
Methodology
Gas chromatography with flame ionization detection was employed under controlled temperature ramping to achieve baseline separation of enantiomers.
Used Instrumentation
- Capillary column: Rt-βDEXsa, 30 m × 0.25 mm ID, 0.25 μm film thickness (cat. #13109)
- Oven program: 60 °C to 110 °C at 1 °C/min with a 30-minute hold
- Carrier gas: Hydrogen at 40 cm/s linear velocity (set at 60 °C)
- Detector: Flame ionization detector (FID) at 220 °C
Main Results and Discussion
The method achieved complete resolution of cis- and trans-rose oxide enantiomers (1a, 1b, 2a, 2b), R- and S-linalool (5a, 5b), and R- and S-citronellol (6a, 6b).
Additional components such as isomenthone, menthone, geraniol, and citronellyl formate were also well separated.
The gradual temperature ramp ensured sharp peaks and minimal coelution, facilitating accurate quantification.
Benefits and Practical Applications
The approach enables reliable enantiomeric purity assessment in fragrance formulations, ensuring consistency and authenticity.
It supports regulatory compliance and enhances research in flavor and fragrance chemistry.
Future Trends and Possibilities
Emerging chiral stationary phases and multidimensional GC techniques promise faster analysis and higher resolution.
Integration with mass spectrometry can expand detection capabilities for trace-level enantiomeric analysis.
Conclusion
Rt-βDEXsa GC-FID provides an effective, reproducible method for chiral separation of geranium oil constituents.
Its application enhances quality control and research in the flavor and fragrance industry.
References
No literature references were provided in the source document.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
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