OBJECTIVES: To investigate the possibility of applying diffusive air sampling and urinalysis (for mother compound and metabolites) to the monitoring of exposure of factory workers to 1-butanol. METHODS: The performance of carbon cloth in adsorbing 1-butanol vapor in air was studied by experimental exposure of the cloth to 1-butanol at 50, 100, 200 or 400 ppm for up to 10 h. 1-Butanol in the exposed cloth was extracted with carbon disulfide and this was followed by gas-chromatographic (GC) analysis. Urine samples were collected from factory workers occupationally exposed to 1-butanol and from rats exposed experimentally to 1-butanol vapour (up to 200 ppm). The urine samples were analyzed by GC without any pretreatment, or after treatment with hydrochloric acid or hydrolase preparation. RESULTS: The performance of the carbon cloth was such that it adsorbed 1-butanol in proportion to the concentration (up to 400 ppm) and the duration (up to 10 h) of exposure, and responded quantitatively to a 15-min exposure up to 400 ppm. The amount of 1-butanol (after enzymic or acid hydrolysis) in post-exposure urine samples from rats was proportional to the exposure intensity. The proportion of free 1-butanol in total 1-butanol (i.e., free+conjugated) in urine was higher after 100 or 200 ppm exposure (35-40%) than after 50 ppm exposure (about 8%). There was a significant increase in total 1-butanol concentration (but not in free 1-butanol) in shift-end urine samples of workers exposed to 1-butanol at concentrations up to 3 ppm. CONCLUSIONS: Diffusive sampling with carbon cloth as an adsorbent can be applied to ambient air monitoring of exposure to 1-butanol. Urinalysis for 1-butanol after hydrolysis is sensitive enough to detect occupational 1-butanol vapour exposure at 3 ppm.
OBJECTIVES: To investigate the possibility of applying diffusive air sampling and urinalysis (for mother compound and metabolites) to the monitoring of exposure of factory workers to 1-butanol. METHODS: The performance of carbon cloth in adsorbing 1-butanol vapor in air was studied by experimental exposure of the cloth to 1-butanol at 50, 100, 200 or 400 ppm for up to 10 h. 1-Butanol in the exposed cloth was extracted with carbon disulfide and this was followed by gas-chromatographic (GC) analysis. Urine samples were collected from factory workers occupationally exposed to 1-butanol and from rats exposed experimentally to 1-butanol vapour (up to 200 ppm). The urine samples were analyzed by GC without any pretreatment, or after treatment with hydrochloric acid or hydrolase preparation. RESULTS: The performance of the carbon cloth was such that it adsorbed 1-butanol in proportion to the concentration (up to 400 ppm) and the duration (up to 10 h) of exposure, and responded quantitatively to a 15-min exposure up to 400 ppm. The amount of 1-butanol (after enzymic or acid hydrolysis) in post-exposure urine samples from rats was proportional to the exposure intensity. The proportion of free 1-butanol in total 1-butanol (i.e., free+conjugated) in urine was higher after 100 or 200 ppm exposure (35-40%) than after 50 ppm exposure (about 8%). There was a significant increase in total 1-butanol concentration (but not in free 1-butanol) in shift-end urine samples of workers exposed to 1-butanol at concentrations up to 3 ppm. CONCLUSIONS: Diffusive sampling with carbon cloth as an adsorbent can be applied to ambient air monitoring of exposure to 1-butanol. Urinalysis for 1-butanol after hydrolysis is sensitive enough to detect occupational 1-butanol vapour exposure at 3 ppm.
Authors: David M Chambers; Kasey C Edwards; Eduardo Sanchez; Christopher M Reese; Alai T Fernandez; Benjamin C Blount; Víctor R De Jesús Journal: ACS Omega Date: 2021-05-04