STUDIA UNIVERSITATIS BABEŞ BOLYAI, PHYSICA, L, 3, 25 VALIDATED METHODS FOR VOCS DETERMINATION BY GC MS Monica Culea, Onuc Cozar, Dumitru Ristoiu Univ. Babes Bolyai, Dept. of Biomedical Physics, 1 Kogalniceanu str, 34 uj Napoca, Romania e mail: mculea@phys.ubbcluj.ro Qualitative and quantitative methods for measuring volatile organic compounds by pre concentration techniques followed by gas chromatography mass spectrometry (GC MS) analysis were developed. The MS was operated in the SIM and scan modes. The compounds of interest eluted at the column temperature of 3 o C. For the quantitative work, the methods were validated and showed good linearity, precision, accuracy, LOD for the compounds studied. Validation of the methods demonstrated the ability to identify and to measure reliably the yields of BTEX, THM, and other VOCs, by using the proper internal standard. Introduction Volatile organic compounds (VOCs) are of concern since many are toxic and they may also be persistent in the environment. The main source in the environment is petrol, vehicle traffic and indoors, cigarette smoke. They are also present in small quantities in drinking water and food, in paints and adhesives. The methods are validated for the investigation of VOCs in drinking water or air by the emissions from different materials, adhesives, combustion sources or tobacco smoke. Benzene, toluene, ethyl benzene and xylene (BTEX) are widespread pollutants of which the main source in the outside environment is vehicle traffic and indoor the cigarette smoke. They are also present in small quantities in drinking water and food, in painting substances or adhesives. All of these sources contribute to pollution of indoor environments [1 4]. Vehicle movement was confirmed as the dominant influence on benzene and associated VOCs in the atmosphere. The benzene outdoor maximum limit recommended by the European Community is 1 µg. m 3. Occupational maximum exposure limit is 16 mg. m 3. BTEX and VOCs could be find in water, soil, substances of abuse, cigarette smoke, adhesives, in paint and varnish shops, breath or blood. It is calculated that a typical smoker inhales 2 mg benzene daily, compared to.2 mg per day for the nonsmoker. Trihalomethanes (THMs) are volatile disinfection by products (DBPs) in drinking water or recreation waters [5 7]. Chlorination by products in drinking water are very toxic, human carcinogenic compounds. The high priority DBPs include halomethanes, haloacetonitriles, haloketones, haloacids, and halonitromethanes, chloral hydrates, chloropicrin. The THMs (CHX 3, X=halogen) 2
MONICA CULEA, ONUC COZAR, DUMITRU RISTOIU are: chloroform (CH 3 ), bromodichloromethane (CH 2 ), dibromochloromethane (CH 2 ) and bromoform (CH 3 ). The maximum contamination level of 1 µgl 1 for total trihalomethanes in drinking water, set by US Environmental Protection Agency (USEPA) in 1979 was lowered to 8 µgl 1 and is considered to be lowered to 4 µgl 1. The techniques used for the determination of DBPs in drinking water include water extraction procedure as liquid liquid extraction (LLE), purge and trap or headspace followed by gas chromatographic (GC) separation and electro capture detection (ECD) or mass spectrometric (MS) detection. In the last years the number of procedures using extraction of organic compounds from air and water has increased. Trace analyses involve pretreatment: of the samples, extraction and concentration procedure to increase the analyte concentration to within instrument sensitivity. The extraction procedure, internal standard selection and method validation are the steps to follow for quantitative analyses by using gas chromatography mass spectrometric technique (GC MS). The preconcentration step could be: (1) solvent extraction (2) headspace analysis, (3) purge and trap, (4) solid phase extraction (SPE) (column and discs) (5) solid phase microextraction (SPME) and some other modern technique. Gas chromatography mass spectrometry (GC/MS) and GC are the most used quantitative methods for VOCs levels detection in the indoor air and drinking water. The aim of the paper is to demonstrate the validation of analytical methods for the determination of some carcinogenic VOCs as THMs or BTEX.. Experimental Extraction procedure Liquid liquid extraction (LLE for THMs determination): The water sample is shaken with an immiscible organic solvent, methyl tert butyl ether (MTBE). Purge and trap GC MS method The purge and trap concentrator was active charcoal. Standard solutions or drinking water was extracted with a 12 ml/min He, 3 min and followed by desorbtion at 12 o C for 3 min in a U tube containing 5µl dichlormethane. The organic layer is injected into the chromatograph. After extraction, a known quantity of internal standard (pyridine for BTEX, benzene for THMs) was added to the supernatant and analyzed. Apparatus A Trace DSQ Thermo Finnigan quadrupole mass spectrometer coupled with a Trace GC was used. A Rtx 5MS capillary column, 15 m or 3 m length x.25 mm,.25µm film thickness, by using a temperature program from 3 o C kept for some minutes, then increased to 3 o C, in selected ion monitoring (SIM) or scan 21
VALIDATED METHODS FOR VOCS DETERMINATION BY GC MS mode. The GC/MS interface line and the ion source were maintained to 2 o C and 25 o C. Electron energy was 7eV and electron emission 1µA. In the SIM mode [Fig.1] the following important ions are used for THMs: m/z 83 and 85 for chloroform, m/z 83, 85, 129 for dichlorobromomethane, m/z 127, 129 for dibromochloromethane, m/z 129, 173, 252 for bromoform and m/z 78 for the internal standard (benzene) [Fig.2]. PurgeTrapSapcaV1mscan4_5425141814 4/25/25 2:18:15 PM RT:. 9.43 1 3.24 chloroform NL: 1.6E7 Relative Abundance 9 8 7 6 5 4 3 bromodichloromethane chlorodibromomethane TIC F: M S PurgeTrapS apcav1msca n4_542 5141814 2 5.8 bromoform 1 3.89 4.64 8.1 8.52 9.2 3.7 4.53 4.83 5.44 5.87 6.65 7.14 7.95..5 1. 1.5 2. 2.5 3. 3.5 4. 4.5 5. 5.5 6. 6.5 7. 7.5 8. 8.5 9. Time (min) 9.41 PurgeTrapSapcaV1mscan4_5425141814 # 13 RT: 3.26 AV: 1 SB: 15 3.7 3.19, 3.28 3.43 NL: 1.77E5 T: + c SIM ms [ 77.5 78.5, 82.5 83.5, 84.5 85.5, 126.5 127.5, 128.5 129.5, 13.5 131.5, 172.5 173.5, 174.5 175.5, 174.5 175.5, 27.5 28.5, 251.5 252.5] 82.89 1 9 8 Relative Abundance 7 6 5 4 3 84.9 2 1 Fig.1. SIM chromatogram of THMs: chloroform, dichlorobromomethane, chlorodibromomethane, bromoform. Selected ions from the mass spectrum of chloroform, 3.26 min. For BTEX, in the SIM mode, the following important ions from the mass spectra of benzene, toluene, ethyl benzene and xylene [Fig.3] were used: m/z 78 for benzene, m/z 91 and 92 for toluene, m/z 91 and 16 for ethyl benzene and xylenes and m/z 52 and 79 for the internal standard. The method was validated in the range 1 µg and linearity, precision, accuracy and limit of detection (LOD) parameters were studied. 1 8 11 12 13 14 15 16 17 18 19 2 21 22 23 24 25 m/z 8 3 1 175.29 8 3 8 5 5 5 H i l i i l t i l i t, i l 4 7 4 7 8 7 1 2 9 3 5 1 3 3 5 7 9 1 1 8 1 2 3 4 5 6 7 8 9 1 1 1 1 2 1 3 1 2 3 4 5 6 7 8 9 1 1 1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 b e h e m c h ( m a n b ) T r c h o r o m e h a n e ( m a n ) M a n b r o o d o r o 1 2 9 1 7 3 1 1 H 5 5 i l i t, i l i l i t, t i 4 8 2 5 2 7 9 7 9 2 8 1 6 1 3 3 1 1 6 1 7 3 1 2 3 4 5 6 7 8 9 1 1 1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 1 9 2 2 1 2 2 1 3 5 7 9 1 1 1 3 1 5 1 7 1 9 2 1 2 3 2 5 2 7 b h a b ( m a n b ) M e h a n e d b r o m o c h o r o ( m a n ) M e n e r r o m o Fig. 2 The mass spectra of THMs chloroform (CH 3 ), bromodichloromethane (CH 2 ), dibromochloromethane (CH 2 ) and bromoform (CH 3 ). 22
MONICA CULEA, ONUC COZAR, DUMITRU RISTOIU 1 7 8 1 5 5 5 1 i l i 3 9 6 3 7 4 2 6 1 5 1 2 3 4 5 6 7 8 9 b e n ( m a n ) B e n z e i l i l 6 5 3 9 4 5 5 1 2 7 2 3 4 5 6 7 8 9 1 b n e ( m a n ) T o u e 1 1 1 6 5 5 i l i t l i l i l 1 6 7 7 5 1 6 5 7 7 3 9 5 1 3 9 6 5 2 7 1 5 2 7 1 2 3 4 5 6 7 8 9 1 1 1 1 2 1 2 3 4 5 6 7 8 9 1 1 1 1 2 ( m a n b ) E h y b e n z e n e ( m a n b ) p X y e n e 1 7 9 N 5 2 5 i l i i i 3 9 2 7 2 3 4 5 6 7 8 9 b e ( m a n ) P y r d n Fig.3 Mass spectra and chemical formula of BTEX and the internal standard (pyridine) Results Methods validation Aliquot samples containing 2, 1, 3 and 6 ng and 2, 4, 6, 8, 1µg BTEX were adsorbed with a pump on 3 mg active coal at a flow rate of 6 ml. min 1 and then were extracted in 1ml dichloromethane. 1mg of pyridine as internal standard was added at each sample. Table 1 presents the linearity parameters obtained in the range 1µg and 6 ng for BTEX, by using 1mg pyridine or respectively 2 ng pyridine as internal standards and for chloroform, in the range 2 µg/l.. Precision studied for the aliquot samples of 4 and 8 µg showed R.S.D. values between 6.5 22 % and respectively between 7.5 25.8%. The accuracy R.S.D. calculated were between 7.6 24.4% for the sample of 4µg and between 2.5 24.9% for the sample of 8 µg. Table 2 presents the results obtained for precision and accuracy. A limit of detection of.1 µg was obtained for the VOCs studied. The separation chromatogram for BTEX in the SIM mode is presented in Fig. 4. A 9 minute temperature program was used. Some volatile compounds identified in 23
VALIDATED METHODS FOR VOCS DETERMINATION BY GC MS the tobacco smoke extract are shown in Fig.5. Table 3 shows the BTEX levels measured in the air contaminated with varnish or adhesive, as well as the indoor pollutants found in a shoe maker workshop. In the last column, the ppm levels for an outdoor air sample were obtained after a short sampling time, 1 L air, in a small parking area, 1 m to a truck with engine running at rest. Table 4 compares some indoor air values for BTEX measured in the mainstream smoke of a Winston cigarette, in the side stream smoke of a Kent cigarette, in the laboratory room (4 m 3 ) and in a pub. The laboratory room was not ventilated during the experiment and the pub was very poor ventilated. RT:. 7.99 1 95 9 85 8 75 7 65 IS 2.19 NL: 5.22E7 TIC MS 2BTEX4µ ga Relative Abundance 6 55 5 45 4 B E 35 3 1.36 T (m+p)x 25 2 4.6 2.52 4.19 15 1 ox 5 1.11 1.6 4.61 1.88 3.62 5.18 5.43 5.82 3.4 6.34 4.77 6.89 7.8 1.53 3.4 7.52..5 1. 1.5 2. 2.5 3. 3.5 4. 4.5 5. 5.5 6. 6.5 7. 7.5 Time (min) Fig.4 Chromatographic separation of BTEX and the internal standard (IS). 9 min temperature program: 3 o C (2 min), 1 o C/min to 7 o C then 5 o C/min to 22 o C, SIM mode Discussion The SIM GC/MS methods developed for VOCs determinations in indoor air and drinking water are good and rapid. The validation of the methods gave good values for precision, R.S.D. of 6.5 25 % and accuracy, R.S.D. between 2.5 24.9%. The limit of detection was 1 ppb. The methods tested for applications showed ppm indoor values or µg/cigarette values for tobacco smoke (Table 3 and 4). The precision of the repeated measurements gave R.S.D. lower than 1 %. The measurement of THMs in our town distribution system showed the following values: CH 3 : 9 µg/l; CH 2 :3.9 µg/l; CH 2 :1.7µg/l. Table 1 Linearity for VOCs Range: 1µg (IS: 1mg pyridine) Compound Regression curve r B y=.39x+.92.932 T y=.39x+.123.927 E y=.47x+.235.923 24
MONICA CULEA, ONUC COZAR, DUMITRU RISTOIU X y=.38x+.21.922 Range: 6ng (IS: 2ng pyridine) B y=.2x+.5.98 T y=.1x+.39.95 E y=.1x+.2.97 X y=.3x+.5.98 Chloroform y=.9121x+.313.975 RT: 1.5 9.2 1.1 1 55 NL: 3.87E8 TIC MS KentbTEX 5 45 2 4 Relative Abundance 35 3 25 2 1.35 3 15 2.5 1 5 2 22 1.66 21 7 14 16 8.63 1.93 2.59 4 5 3.16 6 8 15 17 18 19 4.6 9 4.73 1 11 5.2 1213 1.5 2. 2.5 3. 3.5 4. 4.5 5. 5.5 6. 6.5 7. 7.5 8. 8.5 9. Time (min) Fig.5 The VOCs identified in a tobacco smoke extract (SCAN mode): 1. chloroform; 2.benzene; 3. toluene; 4.octane; 5.tatrachloroethylene; 6.ethyl benzene; 7. (m+p) xylene; 8 o xylene; 9. nonane; 1. camphene; 11. 1,3,5 trimethylbenezene; 12. 1,2,3 trimethylbenzene; 13. decane; 14. limonene; 16. undecane; 17. dodecane; 19. cinnamaldehyde; 2. nicotine; 21. dibutylphtalate; 22. nonadecene Table 2 Precision and accuracy of the method for indoor air BTEX Compound Concentration(µg) Comp/IS Precision Accuracy n Added Measured SD RSD(%) RSD(%) B 4 4 43.2.18.4 22.2 7.6 T 4 4 36.75.16.1 6.5 8.1 E 4 4 3.91.17.2 11.8 22.7 X 4 4 3.23.13.2 15.4 24.4 B 3 8 99.9.4.3 7.5 24.9 T 3 8 75.4.31.8 25.8 5.8 E 3 8 82..41.5 12.2 2.5 X 3 8 75.2.31.5 16.1 6. 25
VALIDATED METHODS FOR VOCS DETERMINATION BY GC MS BTEX (ppm) determination in some indoor and outdoor air measurements (n=2) Compound varnish adhesive shoe maker outdoor air B 38.81 6.15 21.43.24 T 41.31 157.86 95.85.1 E.55 1.5 X 1.79 2.56.7 Table 3 Table 4 BTEX determination in tobacco smoke extracts (n=2) Compound Winston Kent lab. pub µg/cig. ppm. ppm ppm B 14.86 44.6 21.26 5.97 T 229.4 76.36 15.3 37.38 E.5 4.88 5.6.21 X 37.69 3.99 2.55 Conclusions The methods developed demonstrate that GC MS technique is the best choice for VOCs quantitation at trace levels. References 1. M De Bortoli, S Kephalopoulos, S Kirchner, H Schauenburg, H Vissers, State of the art in the measurement of volatile organic compounds emitted from building products: results of European interlaboratory comparison, Indoor Air 1999; 9(2): 13 16. 2. SS Cox, JC Little, AT Hodgson, Measuring concentrations of volatile organic compounds in vinyl flooring. J Air Waste Manag Assoc 21; 51(8): 1195 21. 3. SC Lee, NH Kwok, H Guo, WT Hung,: The effect of wet film thickness on VOC emissions from a finishing varnish,sci Total Environ 23; 32(1 3): 75 84. 4. WA Mcenny, KD Oliver, HH Jacumin Jr, EH Daughtrey Jr, Ambient level volatile organic compound (VOC) monitoring using solid adsorbents recent US EPA studies, J Environ Monit 22; 4(5): 695 75. 5. TC Che n, GR Her., On line monitoring of trihalomethanes in drinking water using continuous flow purge and cryofocusing gas chromatography mass spectrometry,.j Chromatogr A. 21, 927(1 2):229 35. 6. FL Cardinali, DL Ashley, JC Morrow, DM Moll, BC Blount,. Measurement of trihalomethanes and methyl tertiary butyl ether in tap water using solidphase microextraction GC M,S.J Chromatogr Sci. 24,42(4):2 648. 26
MONICA CULEA, ONUC COZAR, DUMITRU RISTOIU 7. HA Duong, M Berg, MH Hoang, HV Pham,H Gallard, W Giger, U von G u n ten, Trihalomethane formation by chlorination of ammonium and bromidecontaining groundwater in water supplies of Hanoi, Vietnam, Water Research 37 (23) 3242 325 27