Ethnic differences in biological monitoring of several organic solvents. I. Human exposure experiment.

OBJECTIVES: In order to improve the reliability of biological monitoring and the development of biological limit values, ethnic differences for several organic solvents were studied in Orientals and Caucasians. METHODS: Six Caucasian and six Oriental volunteers were exposed to each organic solvent in an exposure chamber for 6 h. Exposure concentration to each organic solvent studied was 50 ppm for perchloroethylene, 50 ppm for styrene and 100 ppm for m-xylene, respectively. Biological monitoring was carried out for the parent organic solvents in exhaled air and in blood, and for the metabolites in urine during and after exposure. RESULTS: Caucasians showed higher concentrations of perchloroethylene in exhaled air than Orientals after exposure. But Caucasians showed lower concentrations of styrene in the exhaled air than Orientals during the second half of exposure and after it. Orientals showed lower concentrations of urinary metabolites than Caucasians except for mandelic acid. There were no statistically significant differences in the concentrations of solvent in blood for all three solvents. CONCLUSIONS: Implications of these differences in biological levels, under identical exposure conditions, are discussed in the context of biological monitoring

Biological monitoring of tetrahydrofuran: contribution of a physiologically based pharmacokinetic model

A seven-compartment physiologically based pharmacokinetic (PBPK) model was developed to predict biological levels of tetrahydrofuran under various exposure scenarios. Affinities for the tissue were estimated from measurements of liquid-gas partition coefficients for water, olive oil, and blood. Metabolism was assumed to follow a rapid first order reaction. urinary excretion was simulated considering passive reabsorption of tetrahydrofuran in the tubules. The validity of the model was tested by comparison with available experimental and field data. Agreement was satisfactory with all studies available except one, which showed much higher results than expected. The source of this difference could not be identified, but cannot be explained by different exposure conditions, such as duration, concentration, or physical work load. However, it is recommended that this particular study not be used in the establishment of a biological exposure index. Simulation of repeated occupational exposure with the PBPK model allowed the prediction of biological levels that would be reached after repeated exposure at the American Conference of Governmental Industrial Hygienists' threshold limit value, time-weighted average of 200 ppm. For samples taken at the end of the shift, the PBPK model predicts 5.1 ppm for breath, 57 mumol/L (4.1 mg/L) for venous blood, and 100 mumol/L (7.2 mg/L) for urine

Phenotype-dependent inhibition of human alpha 1-antitrypsin by 1,6-hexane diamine in vitro

Blood donors and patients from pulmonary wards gave serum specimens for the assay of their alpha 1-antitrypsin activity and phenotype. The same specimens were then incubated at the room temperature overnight with increasing concentrations of 1,6-hexane diamine. The 5 mM amine concentration caused a significant decrease in heterozygous antitrypsins (M1M2, M1M3, M2M3 and M1S) activity while it was less in the homozygous (M1M1 and M2M2) antitrypsin phenotypes. The SS and ZZ phenotypes showed a very low initial activity which was, however, further reduced. Analysis for the antitrypsin protein showed a simultaneous loss of its activity. The data suggest that heterozygous antitrypsin carriers may be more prone to the effects of inhaled amines despite their 'normal' phenotypic constitution