Development and Validation for Quantitative Determination of Genotoxic Impurity in Gemfibrozil by Gas Chromatography with Mass Spectrometry
Abstract
:1. Introduction
2. Materials and Methods
2.1. Materials and Reagents
2.2. Equipment
2.3. Chromatographic Conditions
2.4. Mass Spectrometer Conditions
2.5. Impurity Standard and Test Sample Solution Preparation
3. Results
3.1. Optimization of Mass Spectrometric Parameters
3.2. Optimization of Chromatographic Conditions
3.3. Method Validation
3.4. Specificity and System Suitability
3.5. Limit of Detection, Limit of Quantification, Precision for Limit of Quantification
3.6. Linearity
3.7. Method Precision
3.8. Intermediate Precision
3.9. Accuracy
3.10. Robustness
3.11. Standard and Spike Solution Stability
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Instrument Setup | Details | ||
---|---|---|---|
GC Parameters | |||
Chromatographic system | Agilent Technologies 7890B GC system | ||
GC Column | USP phase G27, 30 m length, 0.32 mm internal diameters, 1.5 µm film thickness | ||
Carrier Gas | Helium | ||
Column Mode | Constant Flow | ||
Gas flow | 2 mL/min | ||
Injector (Heater) | 200 °C | ||
Volume of injection | 2 microliters | ||
Oven Programming | Ramping (°C/min) rate | Temperature | Hold time in minutes |
- | 40 (°C) | 0 | |
15 | 250 (°C) | 6 | |
Split flow | 20 | ||
Run time | 20 min | ||
Mass spectrometry conditions | |||
MS system | Agilent Technologies 7010B GC/TQ | ||
Ion source and Detection mode | EI and MRM | ||
For qualification (m/z) | 76 amu → 39 amu | ||
For quantification (m/z) | 76 amu → 41 amu | ||
Dwell time (in milliseconds) | 100 | ||
Collision energy (CE) | 8 v | ||
Gain Factor | 20 | ||
Detector off (MS -Off) | 4 min | ||
Temperature of Source (°C) | 230 | ||
Temperature Transfer Line (°C) | 240 | ||
MS Quad temperature (°C) | 150 |
Parameters | Acceptance Criteria | Observation |
---|---|---|
Specificity and SST | Area % RSD of allyl chloride peak should be ≤15.0. | 3.5% |
RT % RSD of allyl chloride peak should be ≤5.0. | 0.8% | |
RT of allyl chloride peak. | 2 min | |
Any blank Interference | Not observed | |
Limit of detection | Limit of detection Concentration | 0.005 ppm |
Signal-to-noise ratio should be ≥3 | 22 | |
Limit of quantification | Limit of quantification Concentration | 0.01 ppm |
Signal-to-noise ratio should be ≥10 | 45 | |
Precision for Limit of quantification | Area % RSD of allyl chloride peak from 6 injections of LOQ solution should be ≤20.0% | 4.8% |
Linearity and Range | Range for allyl chloride | 0.01 to 0.045 ppm |
Correlation coefficient for allyl chloride linearity solutions should be ≥0.99 | 0.99 | |
Square of the correlation coefficient for allyl chloride linearity solutions should be ≥0.99 | 0.99 |
Parameters | Acceptance Criteria | Observation |
---|---|---|
Method precision | Area % RSD of allyl chloride peak from six preparations of spiked samples should be ≤15.0. | 5.5% |
Intermediate precision | Area % RSD of allyl chloride peak from six preparations of spiked samples should be ≤15.0. | 4.8% |
Area % RSD of allyl chloride peak from 12 preparations of spiked samples from MP and IP should be ≤20.0. | Results with in acceptance limit. | |
Accuracy | The average recovery should be between 70% to 130% for LOQ spiked solution. | 94.40% |
Average recovery should be between 80% to 120% for 50% spiked solution. | 96.60% | |
Average recovery should be between 80% to 120% for 100% spiked solution. | 98.50% | |
Average recovery should be between 80% to 120% for 150% spiked solution. | 97.30% | |
Robustness | Plus flow: concentration difference and retention time of allyl chloride spiked sample. | 2.1%, 1.9 min |
Minus flow: concentration difference and retention time of allyl chloride spiked sample. | 1.4%, 2.1 min | |
Plus oven temperature: concentration difference and retention time of allyl chloride spiked sample. | 2.6%, 1.9 min | |
Minus oven temperature: concentration difference and retention time of allyl chloride spiked sample. | 1.7%, 2.1 min | |
Standard and spike solution Stability | Allyl chloride standard and spiked solutions were observed for 48 h under ambient laboratory temperature (25 ± 5 °C) and under refrigeration (2–8 °C). | Both solutions are Stable |
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Chittireddy, H.N.P.R.; Kumar, J.V.S.; Bhimireddy, A.; Shaik, M.R.; Hatshan, M.R.; Khan, M.; Alwarthan, A.; Shaik, B. Development and Validation for Quantitative Determination of Genotoxic Impurity in Gemfibrozil by Gas Chromatography with Mass Spectrometry. Separations 2023, 10, 145. https://doi.org/10.3390/separations10030145
Chittireddy HNPR, Kumar JVS, Bhimireddy A, Shaik MR, Hatshan MR, Khan M, Alwarthan A, Shaik B. Development and Validation for Quantitative Determination of Genotoxic Impurity in Gemfibrozil by Gas Chromatography with Mass Spectrometry. Separations. 2023; 10(3):145. https://doi.org/10.3390/separations10030145
Chicago/Turabian StyleChittireddy, Hari Naga Prasada Reddy, J. V. Shanmukha Kumar, Anuradha Bhimireddy, Mohammed Rafi Shaik, Mohammad Rafe Hatshan, Mujeeb Khan, Abdulrahman Alwarthan, and Baji Shaik. 2023. "Development and Validation for Quantitative Determination of Genotoxic Impurity in Gemfibrozil by Gas Chromatography with Mass Spectrometry" Separations 10, no. 3: 145. https://doi.org/10.3390/separations10030145
APA StyleChittireddy, H. N. P. R., Kumar, J. V. S., Bhimireddy, A., Shaik, M. R., Hatshan, M. R., Khan, M., Alwarthan, A., & Shaik, B. (2023). Development and Validation for Quantitative Determination of Genotoxic Impurity in Gemfibrozil by Gas Chromatography with Mass Spectrometry. Separations, 10(3), 145. https://doi.org/10.3390/separations10030145