Your search keyword '"Xylenes urine"' showing total 3 results

1. Associations of personal urinary volatile organic compounds and lung function in children.

Author

Park D, Ha EK, Jung H, Kim JH, Shin J, Kim MA, Shin YH, Jee HM, and Han MY

Subjects

Humans, Child, Male, Female, Vital Capacity, Spirometry, Forced Expiratory Volume, Skin Tests, Sorbic Acid analogs & derivatives, Sorbic Acid analysis, Environmental Exposure adverse effects, Environmental Exposure analysis, Respiratory Function Tests, Xylenes urine, Benzene analysis, Airway Resistance, Benzene Derivatives urine, Air Pollutants urine, Air Pollutants analysis, Air Pollutants adverse effects, Asthma urine, Asthma physiopathology, Hippurates urine, Oscillometry, Lung, Volatile Organic Compounds urine

Abstract

Background: We investigated the correlation between urine VOC metabolites and airway function in children exposed to anthropogenic volatile organic compounds (VOCs), notable pollutants impacting respiratory health., Methods: Out of 157 respondents, 141 completed skin prick tests, spirometry, IOS, and provided urine samples following the International Study of Asthma and Allergies in Childhood (ISAAC)-related questions. Allergic sensitization was assessed through skin prick tests, and airway functions were evaluated using spirometry and impulse oscillometry (IOS). Forced expiratory volume in 1 s (FEV1), forced vital capacity (FVC) was recorded and FEV1/FVC ratio was calculated. Airway mechanics parameters including respiratory resistance at 5 Hz (Rrs5) mean respiratory resistance between 5 Hz and 20 Hz (Rrs5-20), were also recorded. Urine concentrations of metabolites of benzene, ethylbenzene, toluene, xylene, styrene, formaldehyde, carbon-disulfide were analyzed by gas chromatography/tandem mass spectroscopy., Results: The median age at study participation was 7.1 (SD 0.3) years. Muconic acid (benzene metabolites) and o-methyl-hippuric acid (xylene metabolites) above medians were associated with a significant increase in Rrs5 (muconic acid: aβ = 0.150, p  = .002; o-methyl-hippuric acid: aβ = 0.143, p  = .023) and a decrease in FEV1/FVC (o-methyl-hippuric acid: aβ = 0.054, p  = .028) compared to those below median. No associations were observed for Rrs5-20 and FEV1 between the groups categorized as above and below the median (all parameter p values > .05)., Conclusions: Elevated levels of benzene and xylene metabolites were associated with a significant increase in Rrs5 and a decrease in FEV1/FVC, related to increased resistance and restrictive lung conditions compared to individuals with concentrations below the median.

Published

2024

2. Evaluation and modeling of the impact of coexposures to VOC mixtures on urinary biomarkers.

Author

Marchand A, Aranda-Rodriguez R, Tardif R, Nong A, and Haddad S

Subjects

Adolescent, Adult, Benzene Derivatives pharmacokinetics, Benzene Derivatives urine, Biomarkers blood, Biomarkers urine, Chloroform administration & dosage, Computer Simulation, Cresols urine, Hippurates urine, Humans, Inhalation Exposure, Male, Mandelic Acids urine, Predictive Value of Tests, Toluene pharmacokinetics, Toluene urine, Urinalysis, Volatile Organic Compounds administration & dosage, Volatile Organic Compounds blood, Xylenes pharmacokinetics, Xylenes urine, Young Adult, Chloroform pharmacokinetics, Chloroform urine, Environmental Monitoring methods, Models, Biological, Volatile Organic Compounds pharmacokinetics, Volatile Organic Compounds urine

Abstract

Context: Urinary biomarkers are widely used among biomonitoring studies because of their ease of collection and nonintrusiveness. Chloroform and TEX (i.e., toluene, ethylbenzene, and m-xylene) are chemicals that are often found together because of common use. Although interactions occurring among TEX are well-known, no information exists on possible kinetic interactions between these chemicals and chloroform at the level of parent compound or urinary biomarkers., Objective: The objective of this study was therefore to study the possible interactions between these compounds in human volunteers with special emphasis on the potential impact on urinary biomarkers., Materials and Methods: Five male volunteers were exposed by inhalation for 6 h to single, binary, and quaternary mixtures that included chloroform. Exhaled air and blood samples were collected and analyzed for parent compound concentrations. Urinary biomarkers (o-cresol, mandelic, and m-methylhippuric acids) were quantified in urine samples. Published PBPK model for chloroform was used, and a Vmax of 3.4 mg/h/kg was optimized to provide a better fit with blood data. Adapted PBPK models from our previous study were used for parent compounds and urinary biomarkers for TEX., Results: Binary exposures with chloroform resulted in no significant interactions. Experimental data for quaternary mixture exposures were well predicted by PBPK models using published description of competitive inhibition among TEX components. However, no significant interactions were observed at levels used in this study., Conclusion: PBPK models for urinary biomarkers proved to be a good tool in quantifying exposure to VOC.

Published

2016

3. Metabolic interaction and disposition of methyl ethyl ketone and m-xylene in rats at single and repeated inhalation exposures.

Author

Liira J, Elovaara E, Raunio H, Riihimäki V, and Engström K

Subjects

Administration, Inhalation, Animals, Butanones administration & dosage, Butanones pharmacokinetics, Drug Interactions, Hippurates urine, Liver metabolism, Male, Rats, Rats, Inbred Strains, Tissue Distribution, Xylenes administration & dosage, Xylenes pharmacokinetics, Xylenes urine, Butanones metabolism, Xylenes metabolism

Abstract

1. Rats were exposed to m-xylene (300 ppm) and methyl ethyl ketone (MEK, 600 ppm) vapour, separately and in combination. 2. Repeated exposures to m-xylene enhanced liver drug-metabolizing capacity, whereas MEK showed no effects. After mixed exposure the cytochrome P-450-dependent monooxygenase activities were additively or synergistically induced. 3. In the presence of MEK the overall metabolism of xylene was strongly inhibited both after single and repeated exposures, an effect accompanied by elevation of xylene concentration in blood (18-29%) and fat (25-32%). 4. The 24-h excretion of the urine metabolites of m-xylene was decreased by 22-24% in mixed exposures: the excretion of methylhippuric acid was decreased (29%), but that of 2,4-dimethylphenol increased (9-35%). 5. After repeated inhalation exposures the excretion of xylene metabolites in urine was consistently higher, whereas the concentrations of xylene in fat (but not the concentration of MEK) were lower than after a single treatment, conceivably due to accelerated metabolic clearance of xylene. 6. Thioether excretion in urine was enhanced in xylene-treated rats (7-13-fold), but was not influenced by the induced changes in the metabolism of xylene. Xylene inhalation caused liver GSH to decrease slightly (10%), as did inhalation of MEK, but the latter did not enhance the excretion of thioethers. 7. MEK is a potent inhibitor of the side-chain oxidation of m-xylene producing methylhippuric acid, but not of its ring oxidation to 2,4-dimethylphenol, and exhibits a synergistic inducing effect on liver enzymes responsible for the oxidation of m-xylene. The increased ring oxidation of m-xylene was not associated with increased production of reactive metabolites indicated by GSH-depletion or thioether formation.

Published

1991