External and internal exposure of wine growers spraying methyl parathion.

Organophosphates, used in agriculture, are readily absorbed through the skin. We investigated the relationship between dermal and inhalative methyl parathion exposure and the plasma levels. Twenty-three healthy wine growers sprayed the insecticide for 50 min. Fluorescent brilliant sulfoflavin was added to the spraying fluids and filter papers were fixed on the subjects. The filter papers were used to evaluate the amount of brilliant sulfoflavine on the unprotected skin fluorometrically. Inhalative exposure was measured with personal air sampler. Plasma concentrations of methyl parathion and its metabolite methyl paraoxon were determined with gas chromatography. Cholinesterase activity in serum and erythrocytes was measured before and after exposure. Some wine growers wore protective clothes, none protective gloves. Dermal exposure ranged up to 12,044 microg, inhalative to 22 microg. Maximum plasma concentration of methyl parathion was 12.1 microg/l. Methyl paraoxon was not detectable. Cholinesterase activity did not decrease. Dermal exposure correlated with the methyl parathion plasma level (Spearman's rho=0.72, p<0.001). In conclusion, dermal exposure exceeded inhalative exposure considerably. Measuring dermal deposition with the brilliant sulfoflavin technique may provide a good estimate of the internal load with methyl parathion. Preventive measures should be improved as toxic effects of repeated exposure to low doses of methyl parathion cannot be excluded.

Acute effects of low doses of methyl parathion on human EEG.

Biological monitoring of workers exposed to organophosphates consists mainly of measuring serum or erythrocyte cholinesterase activity. However, animal experiments and a field study suggest that quantitative analysis of EEG may be more sensitive. In a parallel group design, 25 farmers were investigated, spraying methyl parathion or water for 50min. EEG was recorded before and after spraying. Serum and erythrocyte cholinesterase activity was compared with intraindividual pre-exposure values. Plasma methyl parathion concentrations ranged up to 12.1µg/l, methyl paraoxon was not detectable. Based on plasma concentrations, two exposed subgroups were defined. In EEG recorded with closed eyes, α(1)-power increased insignificantly (Kruskal-Wallis test) in both subgroups. ß(1)-power was enhanced in both exposed subgroups, reaching significance (p≤0.05) at five of 17 electrodes. Spearman's rank correlation showed a significant association between methyl parathion plasma concentration and the median of ß(1)-band power of the 17 electrodes (rho=0.48, p=0.015). Cholinesterase activity did not decrease. On a group basis, EEG is possibly more sensitive than cholinesterase. EEG changes suggest brain cholinesterase inhibition following low exposure to methyl parathion.