© Springer-Verlag Berlin Heidelberg 2005 and styrene by Xiao-Pen Lee and Keizo Sato Introduction Toluene, benzene, xylene and styrene are being widely used for chemical product material
Trang 1© Springer-Verlag Berlin Heidelberg 2005
and styrene
by Xiao-Pen Lee and Keizo Sato
Introduction
Toluene, benzene, xylene and styrene are being widely used for chemical product materials, solvents and constituents of adhesives and paints, and thus sometimes cause poisoning inci-dents by inhaling their gas at chemical product-manufacturing factories Th e abuse of thinner solvents, containing toluene, benzene and xylene, is now a social problem especially for young people Th ere are many crimes and poisoning incidents involving the thinner solvent abuse Recently, styrene leaking from new building materials is an object of interest, because it causes the sick house syndrome
Th e above four solvents are rapidly absorbed into human body by inhalation, per os
and percutaneously to cause various disturbances, such as suppression of the central nervous system In addition, benzene and styrene are being regarded as carcinogenic compounds For analysis of toluene, benzene, xylene and styrene, the conventional GC methods with packed columns are being used [1–10] In this chapter, a method of their analysis for human blood using headspace wide-bore capillary GC is presented
Reagents and their preparation
• Standard solutions: toluene, benzene or each isomer a of xylene of special grade is dissolved
in methanol to prepare each 1 mg/mL solution
• Internal standard (IS) solution: aniline of special grade is dissolved in methanol to give
10 mg/mL solution
GC conditions
Column: an Rtx-BAC2 wide-bore capillary column (30 m × 0.53 mm i d., fi lm thickness 2.0 µm, Restek, Bellefonte, PA, USA)
GC conditions; instrument: a Shimazu GC-14B gas chromatograph (Shimadzu Corp., Kyoto, Japan); detector: FID; column (oven) temperature: 30 °C (1 min) → 15 °C/min → 240 °C injection and detector temperature: 240 °C; carrier gas: He; its fl ow rate: 5.0 mL/min
Trang 2i A 0.5 mL volume of whole blood, 20 µL (200 µg) of IS solution, 1.5 mL of distilled water and 0.6 g of solid NaCl b are placed in a 7.5 mL volume vial, stoppered with a silicone-sep-tum cap and mixed well
ii Th e vial is heated at 100 °C with stirringc on an aluminum block heater Aft er 15 min of heating, about 0.6 mL of the headspace vapor is drawn into a gas-tight syringed and the volume of the vapor is reduced to 0.3 mLe by pushing the plunger It is immediately in-jected into GC for analysis
iii Quantitation: to each 0.5 mL of blank whole blood, one of the known amounts of each solvent and 200 µg of IS are added to construct a calibration curvef,consisting of concen-tration of a solvent on the horizontal axis and peak area ratio of a solvent to IS on the verti-cal axis for enabling verti-calculation of a concentration of a test compound in whole blood
Assessment of the method
> Figure 7.1 shows a headspace wide-bore capillary gas chromatogram obtained from 0.5 mL
whole blood, to which toluene, benzene, 3 kinds of xylene isomers and styrene, 3 µL (3 µg) of each, together with 20 µL (200 µg) of IS solution, had been added Every peak was separated
well from each other except for m- and p-xylenes Th e background was clean with few impu-rity peaks Th e extraction effi ciencies (recoveries) for each organic solvent are 3.1–5.2 % Good linearity of the calibration curve can be obtained in the range of 0.5–5.0 µg/0.5 mL for each compound; the detection limit is equally about 0.2 µg/0.5 mL
It is impossible to separate m-xylene from p-xylene with the present Rtx-BAC2 wide-bore
capillary column To separate such isomers, the use of a packed column with Bentone-34 or a chiral capillary column, such as an α-DEX 120 capillary column (Supelco, Bellefonte, PA, USA), is recommendable
Toxic and fatal concentrations and poisoning symptoms
Although the poisoning eff ects of toluene and benzene vary according to diff erent individuals, the oral ingestion of 15–20 mL toluene generally causes serious toxicity Th e fatal dose of ben-zene is estimated to be about 100 mL; but there was a case in which a subject died aft er oral in-gestion of only 15 mL benzene Th e atmospheric concentration of toluene at 2,000 ppm is dan-gerous for humans [11] Th ere is a possibility of death aft er single inhalation of 10,000 ppm gas
of benzene [11] Th e maximum permissible atmospheric concentrations of toluene and benzene are 50 and 0.5 ppm, respectively, according to the Japanese Society of Industrial Hygiene In fatal thinner poisoning cases, the blood concentrations of toluene were reported to be 6–110 µg/mL [3]; in fatal benzene poisoning cases, blood benzene concentrations to be 0.94–38 µg/mL [12]
As symptoms of acute poisoning by exposure to toluene or benzene, immediate headache, vertigo and coma appear, according to severity of poisoning, followed by death fi nally
As symptoms of chronic poisoning by toluene or benzene, hematological disorders, such as aplastic anemia and acute leukemia, together with the symptoms of the central nervous system, can take place
Trang 3Th e toxicity of xylene is lower than that of toluene or benzene, but it also causes acute and chronic poisoning Th e fatal atmospheric concentration of xylene is about 19,000 ppm [13] Its maximum permissible atmospheric concentration is 100 ppm according to the same society
In autopsy cases of self-ignition using gasoline, the blood concentrations of the three xylene isomers were reported to be 46.5–250 µg/mL [14]
As symptoms by styrene poisoning, the disturbances of the central nervous system appear
At 200–400 ppm of atmospheric concentrations of styrene, stimulation of the eye and the re-spiratory organs can occur; by inhalation of 1 % vapor of styrene, a victim can fall into a coma-tose state in a few minutes [15] Aft er chronic exposure to styrene, the side chain of styrene is epoxidized and causes carcinogenicity Th e maximum permissible atmospheric concentration
of the compound defi ned by the same society is 50 ppm In the survived cases of styrene poi-soning, the blood concentrations were reported to be 0.01–1.0 µg/mL [16, 17]
Detection of toluene, benzene, xylene isomers and styrene from whole blood by headspace
capillary GC 1: benzene; 2: toluene; 3: p-xylene; 4: m-xylene; 5: o-xylene 6: styrene; 7: aniline (IS)
Three micrograms each of the above 6 compounds and 200 µg of aniline (IS) were added to
0.5 mL whole blood.
⊡ Figure 7.1
Trang 4a) Th ere are 3 isomers of xylene, viz o-, m- and p-xylene.
b) To improve extraction effi ciency (recovery), the addition of NaCl is eff ective, because of its salting-out eff ect
c) By using a stirrer, the time for extraction can be shortened; the recovery rate is also in-creased also by heating, due to enhanced mobility of molecules
d) When a vial septum made of silicone/Tefl on is used, a 90°cut needle at its tip for the gas-tight syringe is eff ective to prevent the leakage of gas upon piercing through the septum e) Th is procedure of reducing the volume is eff ective for expelling atmospheric air, which has been aspirated into the syringe just aft er taking the needle out of the vial, because of the negative pressure
f) For drawing a calibration curve, 5–6 concentrations of a compound should be plotted to confi rm its linearity
References
1) Wampler TP, Bowe WA, Levy EJ (1985) Dynamic headspace analyses of residual volatiles in pharmaceuticals J Chromatogr Sci 23:64–67
2) Zahlsen K, Rygnestad T, Nilsen OG (1985) Oral intake of a toluene-containing thinner Effects and headspace gas chromatographic analytical diagnosis Arch Toxicol Suppl 8:412–415
3) Takeichi S, Yamada T, Shikata I (1986) Acute toluene poisoning during painting Forensic Sci Int 32:109–115 4) Morinaga M, Hara K, Kageura M et al (1990) A simple, rapid and simultaneous analysis of complex volatile hydrocarbon mixtures in blood using gas chromatography/mass spectrometry with a wide-bore capillary column Z Rechtsmed 103:567–572
5) Kato K, Nagata T, Kimura K et al (1990) Demonstration of ingested thinner Jpn J Legal Med 44:223–226 6) Ghittori S, Fiorentino ML, Maestri L et al (1993) Urinary excretion of unmetabolized benzene as an indicator of benzene exposure J Toxicol Environ Health 38:233–243
7) Kessels H, Hoogerwrf W, Lips J (1992) The determination of volatile organic compounds from EPA method 524.2 using purge and trap capillary gas chromatography, ECD and FID J Chromatogr Sci 30:247–255 8) Otson R, Kumarathasan P (1995) An automated head space analysis method for xylenes and ethylbenzene in blood and water Chemosphere 30:1109–1123
9) Pantarotto C, Fanelli R, Belletti I et al (1980) Determination of styrene in biological specimens by gas chromato-graphy selected ion monitoring distribution in mice Anal Biochem 105:340–347
10) Varner SL, Breder CV, Fazio T (1983) Determination of styrene migration from food-contact polymers into margarine, using azeotropic distillation and headspace gas chromatography J Assoc Off Anal Chem 66:1067– 1073
11) Olson KR (ed) (1994) Poisoning & Drug Overdose, 2nd edn Appleton & Lange, Norwalk, CT, pp 298–300 12) Moffat AC, Jackson JV, Moss MS et al (eds) (1986) Clark’s Isolation and Identification of Drugs, 2nd edn Pharmaceutical Press, London, p 380
13) Ishibashi H (1967) Guide to Organic Solvents Maki-shoten, Tokyo, p 128 (in Japanese)
14) Hattori H, Iwai M, Kurono S et al (1998) Sensitive determination of xylenes in whole blood by capillary gas chromatography with cryogenic trapping J Chromatogr B 718:285–289
15) Patty FA (ed) (1967) Industrial Hygiene and Toxicology, 2nd edn Wiley, New York, p 1222
16) Cherry N, Waldron HA, Wells GG et al (1980) An investigation of the acute behavioral effects of styrene on factory workers Br J Ind Med 37:234–240
17) Klaassen CD (ed) (1996) Casarett and Doull’s Toxicology, 5th edn McGraw-Hill, New York, p 999