DETERMINATION OF NINE VOLATILE NITROSAMINES AND HYDROXY-NITROSAMINES IN CIGARETTE FILLER AND MAINSTREAM TOBACCO SMOKE Mehran SHARIFI, Peter JOZA, Bill RICKERT 69 th TOBACCO SCIENCE RESEARCH CONFERENCE September 20-23, 2015 Naples, Florida, USA LABSTAT INTERNATIONAL ULC. 262 Manitou Drive Kitchener, Ontario, Canada N2C 1L3 Phone: (519) 748-5409 Fax: (519) 748-1654 www.labstat.com Presentation no 28
Objective To develop a sensitive and specific method for quantitative analysis of volatiles and hydroxy-nitrosamines in cigarette filler and mainstream smoke. Historical Methods GC-TEA GC-MS Method Development LC-MS/MS Method Approach Challenges Performance Advantage 2
Volatile Nitrosamines (Cigarette Filler) Historical Approach - GC/TEA 3 g sample Extract with Citrate-Phosphate Buffer + ISTD LPE (Hydromatrix) Concentrate ISTD 1 (NDiPA) ISTD 2 (NDHA) Std Solution KY ref. 3R4F NEMA NDEA NDPA NDBA NPIP NDMA Stabilwax (30 m x 0.32 mm x 1.0 µm) NPYR NMOR 3
20 cigarettes (Citrate/Phosphate Buffer + Filter Pad ) Add ISTD to the Filter Pad Extract (LPE) Buffer with DCM (3 X 50 ml) Volatile Nitrosamines (Mainstream) Historical Approach GC/TEA Extract Filter Pad with DCM extract ISTD 1 (NDiPA) - Filter - Concentrate Alumina Clean-up Concentrate ISTD 2 (NDHA) Fortified Blank NDMA KY ref. 3R4F Stabilwax (30 m x 0.32 mm x 1.0 µm) NEMA NDEA NDPA NDBA NPIP NPYR NMOR 4
Cigarette Filler 1 g sample + Internal Std (NDELA-d 8 ) N-Nitrosodialkanolamines Recent Approach - GC/MS Mainstream Smoke 20 cigarettes (NH 4 SO 3 NH 2 /H 2 SO 4 Buffer) Extracted with 50 ml Water Add Internal Standard (NDELA-d 8 ) Acidified with NH 4 SO 3 NH 2 /H 2 SO 4 Saturation with NH 4 SO 4 Derivatization (MSHFBA) Liquid Phase Extraction with Ethylformate:EtOH Solvent Evaporation (complete dryness) Sample Concentration GC-MS/NCI (NH 3 ) 5
What are the Drawbacks of Historical Methods? Detector Not as specific as Mass Spectrometric techniques GC-TEA (VNA) Solvent (CH 2 Cl 2 ) Health risk, low vapour pressure Chlorinated waste disposal (environment) Inconvenient for GC polar column (frequent maintenance) GC-MS (HO-NA) Derivatization (MSHFBA) Ionization (NCI/NH 3 ) Silylation step requires an aprotic environment (complete dryness prior to the addition of the reagent). CI requires frequent cleaning of the source. Both Methods Chromatographic attributes Analytes peaks exhibit low S:N ratios in samples Complex and highly variable baselines (difficulties to identify and integrate nitrosamine peaks). 6
Method Development Approach / Challenges Ionization Efficiency Mobile Phase Signal Suppression Matrix Effect Interference Reagent Purity 7
Acetonitrile : Formic Acid (1%) Acetonitrile : Ammonium Acetate (2mM) Method Development - LC Mobile Phase and Ionization Efficiency Methanol : Ammonium Acetate (2mM) Methanol : Formic Acid (1%) Acetonitrile : Formic Acid NDMA NEMA Methanol : Ammonium Acetate NDEA 6 5e5 11.03 5 16.71 20.56 0e5 4 0 3 2 0 1 0 0 0 9 8 0 7 0 Intensity (counts) 6 5 4 3 2 1 0 7.78 CH 3 CN : Amm. Acet. 6.47 9.119.34 16.76 14.7915.26 6 8 10 12 14 16 1 time (minutes) Intensity (counts) 0 0 0 0 0 0 0 0 0 0 0 0 00 0 14 16 18 20 22 12 Time,min time (minutes) Intensity (counts) 0 16 18 20 22 24 14 Time,min time (minutes) 8
Method Development - LC Mobile Phase and Ionization Efficiency Response Factor = fct (mobile phase composition) 1400 1200 1000 400 350 300 1400 1200 1000 S:N Ratios 800 600 400 250 200 150 100 800 600 400 200 0 200 50 0 0 NDMA NMOR NPYR NDEA NPIP NEMA CH 3 CN : HCOOH CH 3 CN : CH 3 COO -,NH 4 + CH 3 OH : CH 3 COO -,NH 4 + CH 3 CN : HCOOH combination appeared to be the best compromise for all analytes. 9
Method Development Reagent Water Purity Background Level 3.0 NDMA (m/z 75 43) 2.8 2.6 Intensity (counts) 2.4 2.2 2.0.8.6.4.2 04 NDMA (m/z 75 43) 1% FA solution in type I H 2 O (ASTM D1193-91).0 0 0 0 0 0 0 0 0 10.21 10.21 8 10 12 14 16 18 20 22 24 26 28 30 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 Time,min time (minutes) 1% FA solution in distilled H 2 O 10
Method Development Matrix Effect & Signal Suppression 35000 30000 Lab. No Matrix Fortified (n Blank = 4) Lab. Matrix Fortified (n = Matrix 8) Signal Suppression 87% 100% 90% 80% Intensity (counts) 25000 20000 15000 70% 60% 50% 40% 10000 5000 0 29% 7% 9% D6-NDMA 6 DD8-NPYR 8 D10-NDEA D D14-NDPA 10 -NDEA D 14 30% 20% 10% 0% 11
1.47 7 15. 14.74 18.61 20.10 17.90 20.59 24.39 2.19 Intensity (counts) Fortified KY 3R4F 7. 3 Method Development Signal Suppression - NDMA ) 9.91 Open Scan (m/z 100 500) Intensity (counts) 0 0 4 6 8 10 12 14 16 18 20 2 24 26 2 me,mi n Ti Q p ( ( ) ) ( ) 10.19 10.6012.09 6.49 4.09 9.06 4.59 3.06 7.21 Fortified Reagent Blank 15.37 MS/MS-MRM (m/z 75 43) minutes 16.01 18.37 1.84 2.39 19.4321.09 25.3426 minutes 4 6 8 10 12 14 16 18 20 2 24 26 2 me,mi n Ti Further clean-up or better LC separation? 12
Method Development Reducing Signal Suppression - LC LC C18 (LC) NEMA NDEA Improved separation of polar compounds NDMA NMOR NDiPA NDPA Intensity (counts) 00 0 16.63 7.27 9.54 5.31 19.57 14.65 9 1.59 23.40 4 6 8 10 12 14 16 18 20 2 24 26 28 30 32 34 2 me,mi n Ti (p ) p ( ) p ( ) p C18 + HILIC (LC LC) NDMA NEMA NMOR NDiPA 4 8 10 12 14 16 18 20 2 24 26 28 30 32 34 36 38 4 2 17.78 6 n me,mi Ti NDEA NDPA NDBA D 14 -NDBA NDBA Reduced signal suppression 13 10.41
Findings from Method Development Background Levels NDMA content in deionized water NPYR found in Ethylformate (removal of NDMA from ethylfomate) NMOR/NDBA in Hydromatrix (removal of NDMA from ethylfomate) Detection (APCI + -MS/MS-MRM) Mobile Phase choice LC X LC separation Scope Direct/simultaneous VNA/HO-NA analysis in Mainstream Emission HO-NA in Cigarette Filler requires additional clean-up step 14
Resulting Methodology (Mainstream Emission) Sample Generation 10 Cigarette smoked (Sulfamate buffer traps + glass fiber filter disc) Sample Extraction Extract pad with trap solutions (shake for 30 minutes). Acidify a 12 ml-aliquot of the extract with ammonium sulphamate/h 2 SO 4 Saturate the extract with (NH 4 ) 2 SO 4 Sample Clean-up Clean-up on hydromatrix cartridge (20g) Elute with 70 ml ethyl formate ethanol (98:2, v/v) Evaporate to 1 ml (Rotavap) Sample Analysis LC-APCI + -MS/MS-MRM (40 minutes) 15
Resulting Methodology (Cigarette Filler) Cigarette Filler 1.5 g sample + Internal Std mixture N-Nitrosodialkanolamines Volatile Nitrosamines Extract in 50 ml distilled water Acidify to ph~2 (NH 4 SO 3 NH 2 /H 2 SO 4 ) Saturate with Ammonium Sulfate Liquid Phase Extraction (Ethylformate:EtOH) Concentration Florisil clean-up (MeOH ) Concentration VNA Analysis NDELA/NDiPLA Analysis 16
Analytical Performance Validation Data Analytical Range Sensitivity Precision/Recovery 17
Analytical Calibration range: Analytical Performance Method Linearity Mainstream Smoke : 0.5 200 ng/cig Cigarette Filler: 5.0 1000 ng/g
Method Recovery & Precision Recovery (%) Analytical Performances (Cigarette Filler) Precision (%) NDMA 103±9 8.6 NEMA 95±8 8.5 NDEA 102±9 8.7 NDiPA 95±4 4.6 NDPA 100±6 5.6 NPYR 102±5 4.8 NMOR 96±7 7.0 NPIP 103±8 7.8 NDBA 102±7 6.7 NDELA 103±10 10.2 NDiPLA 97±15 15.2 Method Sensitivity: LOQ Values LC-MS (ng/g) GC-MS (ng/g) GC-TEA (ng/g) NDMA 2.9-3.9 NEMA 4.3-4.5 NDEA 4.5-4.7 NDiPA 1.2-1.9 NDPA 3.2-5.1 NPYR 4.7-5.5 NMOR 1.5-1.8 NPIP 2.9-7.6 NDBA 5.1-7.0 NDELA 2.0 2.6 - NDiPLA 2.5 2.1-19
Method Recovery & Precision Recovery Precision (%) (%) NDMA 100±6 5.9 NEMA 103±3 3.1 NDEA 102±5 5.0 NDiPA 98 ±7 6.9 NDPA 111±6 5.5 NPYR 102±5 4.7 NMOR 100±14 14.4 NPIP 107±6 5.9 NDBA 110±16 14.2 NDELA 102±5 4.6 Analytical Performances (Mainstream Emission) Method Sensitivity: LOQ Values LC-MS (ng/cig) GC-MS (ng/cig) GC-TEA (ng/cig) NDMA 0.59-0.72 NEMA 0.85-0.68 NDEA 1.03-0.70 NDiPA 0.91 - (ISTD) NDPA 0.25-0.76 NPYR 0.66-0.83 NMOR 0.92 - - NPIP 0.29-1.15 NDBA 0.55-1.06 NDELA 0.14 0.11-20
Advantages of Current LC-MS/MS over Historical Methods Unequivocal Mass Spectral Identification (higher accuracy) The LC-MS/MS technique is a quantitative, sensitive, and reliable method for analysis of volatiles and hydroxy-nitrosamines Higher Recovery ( absolute ) in tobacco, cigarette smoke and new generation of tobacco products. Higher Precision (use of isotopically-labelled analogues as ISTD) Higher Sensitivity (higher S:N ratios in samples) Significantly cleaner chromatograms : providing ease of peak integration minimizing the risk of peak misidentification. Safer Lab./personnel Safety (CH 2 Cl 2 ) 21
Acknowledgment Thank you for Your Attention!