Your search keyword '"Bechtold, W. E."' showing total 5 results

1. Markers for carcinogenicity among butadiene-polymer workers in China

Author

Hayes, R. B., Zhang, L., Swenberg, J. A., Yin, S. N., Xi, L., Wiencke, J., Bechtold, W. E., Yao, M., Rothman, N., and Haas, R.

Published

2001

2. Genotoxic markers among butadiene polymer workers in China.

Author

Hayes, R B, Zhang, L, Yin, S, Swenberg, J A, Xi, L, Wiencke, J, Bechtold, W E, Yao, M, Rothman, N, Haas, R, O'Neill, J P, Zhang, D, Wiemels, J, Dosemeci, M, Li, G, and Smith, M T

Abstract

While 1,3-butadiene is carcinogenic in rodents, cancer causation in humans is less certain. We examined a spectrum of genotoxic outcomes in 41 butadiene polymer production workers and 38 non-exposed controls, in China, to explore the role of butadiene in human carcinogenesis. Because in vitro studies suggest that genetic polymorphisms in glutathione S-transferase enzymes influence genotoxic effects of butadiene, we also related genotoxicity to genetic polymorphisms in GSTT1 and GSTM1. Among butadiene-exposed workers, median air exposure was 2 p.p.m. (6 h time-weighted average), due largely to intermittent high level exposures. Compared with unexposed subjects, butadiene-exposed workers had greater levels of hemoglobin N-(2,3,4-trihydroxybutyl)valine (THBVal) adducts (P < 0.0001) and adduct levels tended to correlate, among butadiene-exposed workers, with air measures (P = 0.03). Butadiene-exposed workers did not differ, however, from unexposed workers with respect to frequency of uninduced or diepoxybutane-induced sister chromatid exchanges, aneuploidy as measured by fluorescence in situ hybridization of chromosomes 1, 7, 8 and 12, glycophorin A variants or lymphocyte hprt somatic mutation. Also among the exposed, greater THBVal levels were not associated with increases in uninduced sister chromatid exchanges, aneuploidy, glycophorin A or hprt mutations. Butadiene-exposed workers had greater lymphocyte (P = 0.002) and platelet counts (P = 0.07) and lymphocytes as a percentage of white blood cells were moderately correlated with greater THBVal levels (Spearman's phi = 0.32, P = 0.07). Among butadiene-exposed workers, neither GSTM1 nor GSTT1 genotype status predicted urinary mercapturic acid butanediol formation, THBVal adducts, uninduced sister chromatid exchanges, aneuploidy or mutations in the glycophorin A or hprt genes. Overall, the study demonstrated exposure to butadiene in these workers, by a variety of short-term and long-term measures, but did not show specific genotoxic effects, at the chromosomal or gene levels, related to that exposure.

Published

2000

3. Incense Smoke: Characterization and Dynamics in Indoor Environments

Author

Cheng, Y. S., Bechtold, W. E., Yu, C. C., and Hung, I. F.

Abstract

Burning incense in houses and temples for religious functions is especially common in Asia. Smoke from burning incense is a source of indoor aerosols, and extracts from this smoke are mutagenic in the Ames Salmonella test. This paper describes characterization of the smoke in terms of particle size, shape, concentration, density, and chemical composition. Our data showed that aerosols from incense smoke were spherical droplets with a count median diameter of about 0.13 μm and mass median aerodynamic diameter of 0.28 μm. The particle density was 1.06 ± 0.08 g cm-3. Aerosols produced from incense are therefore similar to other aerosols formed by condensation, such as environmental tobacco smoke found indoors. The aerosol concentration profiles and size distributions within a room during typical burning cycles were monitored. The air ventilation rate in the room was also measured by the SF6 tracer gas method. Respirable aerosol concentrations up to several hundred μg m-3 were produced by burning one to three joss sticks. By modeling the concentration change in the room with time using mathematical equations, we estimated the incense aerosol generation rate as a function of time and the aerosol removal rate constant. This source term information can be used to estimate incense smoke concentration in indoor environments.

Published

1995

4. Identification of benzene oxide as a product of benzene metabolism by mouse, rat, and human liver microsomes.

Author

Lovern, M R, Turner, M J, Meyer, M, Kedderis, G L, Bechtold, W E, and Schlosser, P M

Abstract

Benzene is a ubiquitous environmental pollutant that is known to cause hematotoxicity and leukemia in humans. The initial oxidative metabolite of benzene has long been suspected to be benzene oxide (3,5-cyclohexadiene-1,2-oxide). During in vitro experiments designed to characterize the oxidative metabolism of [14C]benzene, a metabolite was detected by HPLC-radioactivity analysis that did not elute with other known oxidative metabolites. The purpose of our investigation was to prove the hypothesis that this metabolite was benzene oxide. Benzene (1 mM) was incubated with liver microsomes from human donors, male B6C3F1 mice, or male Fischer-344 rats, NADH (1 mM), and NADPH (1 mM) in 0.1 M sodium phosphate buffer (pH 7.4) and then extracted with methylene chloride. Gas chromatography-mass spectrometry analysis of incubation extracts for mice, rats, and humans detected a metabolite whose elution time and mass spectrum matched that of synthetic benzene oxide. The elution time of the benzene oxide peak was approximately 4.1 min, while phenol eluted at approximately 8 min. Benzene oxide also coeluted with the HPLC peak of the previously unidentified metabolite. Based on the 14C activity of this peak, the concentration of benzene oxide was determined to be approximately 18 microM, or 7% of total benzene metabolites, after 18 min of incubation of mouse microsomes with 1 mM benzene. The metabolite was not observed in incubations using heat-inactivated microsomes. This is the first demonstration that benzene oxide is a product of hepatic benzene metabolism in vitro. The level of benzene oxide detected suggests that benzene oxide is sufficiently stable to reach significant levels in the blood of mice, rats, and humans and may be translocated to the bone marrow. Therefore benzene oxide should not be excluded as a possible metabolite involved in benzene-induced leukemogenesis.

Published

1997

5. 135 URINARY EXCRETION OF PHENOL CATECHOL HYDROQUINONE AND MUCONIC ACID BY WORKERS OCCUPATIONALLY EXPOSED TO BENZENE

Author

Bechtold, W. E., Rolhman, N., Yin, S-N, Dosemeci, M., Li, G L, Wang, Y Z, Hayes, R. B., and Smith, M. T.

Published

1995