Breath, urine, and blood measurements as biological exposure indices of short-term inhalation exposure to methanol

Due to their transient nature, short-term exposures can be difficult to detect and quantify using conventional monitoring techniques. Biological monitoring may be capable of registering such exposures and may also be used to estimate important toxicological parameters. This paper investigates relati...

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Published inInternational archives of occupational and environmental health Vol. 71; no. 5; pp. 325 - 335
Main Authors BATTERMAN, S. A, FRANZBLAU, A, D'ARCY, J. B, SARGENT, N. E, GROSS, K. B, SCHRECK, R. M
Format Journal Article
LanguageEnglish
Published Berlin Springer 01.07.1998
Subjects
Adult
Biological and medical sciences
Biomarkers - analysis
Breath Tests
Chemical and industrial products toxicology. Toxic occupational diseases
Female
Humans
Inhalation Exposure
Male
Medical sciences
Methanol - blood
Methanol - pharmacokinetics
Methanol - urine
Middle Aged
Occupational Exposure - analysis
Time Factors
Toxicology
Various organic compounds
Short term
Human
Urine
Expired air
Biological fluid
Biological marker
Exposure
Blood
Biological monitoring
Inhalation
Occupational accident
Occupational medicine
Methanol
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Summary:Due to their transient nature, short-term exposures can be difficult to detect and quantify using conventional monitoring techniques. Biological monitoring may be capable of registering such exposures and may also be used to estimate important toxicological parameters. This paper investigates relationships between methanol concentrations in the blood, urine, and breath of volunteers exposed to methanol vapor at 800 ppm for periods of 0.5, 1, 2, and 8 h. The results indicate factors that must be considered for interpretation of the results of biological monitoring. For methanol, concentrations are not proportional to the exposure duration due to metabolic and other elimination processes that occur concurrently with the exposure. First-order clearance models can be used with blood, breath, or urine concentrations to estimate exposures if the time that has elapsed since the exposure and the model parameters are known. The 0.5 to 2-h periods of exposure were used to estimate the half-life of methanol. Blood data gave a half-life of 1.44+/-0.33 h. Comparable but slightly more variable results were obtained using urine data corrected for voiding time (1.55+/-0.67h) and breath data corrected for mucous membrane desorption (1.40+/-0.38 h). Methanol concentrations in blood lagged some 15-30 min behind the termination of exposure, and concentrations in urine were further delayed. Although breath sampling may be convenient, breath concentrations reflect end-expired or alveolar air only if subjects are in a methanol-free environment for 30 min or more after the exposure. At earlier times, breath concentrations included contributions from airway desorption or diffusion processes. As based on multicompartmental models, the desorption processes have half-lives ranging between 0.6 and 5 min. Preliminary estimates of the mucous membrane reservoir indicate contributions of under 10% for a 0.5-h exposure and smaller effects for longer periods of exposure.
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SourceType-Scholarly Journals-1
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ISSN:0340-0131
1432-1246
DOI:10.1007/s004200050288