One of the steps during the authorization process of plant protection products (PPP) in the European Union is to evaluate the safety of the operator. For this purpose, information on the probable levels of operator exposure during the proposed uses of the PPP is required. These levels can be estimated by using existing mathematical models or from field study data. However, the existing models have several shortcomings, including the lack of data for operator exposure levels during spray applications by hand lance, especially in greenhouses. The present study monitored the potential dermal and inhalation operator exposure from hand-held lance applications of malathion on greenhouse tomatoes at low and high spraying pressures. The methodology for monitoring potential exposure was based on the whole body dosimetry method. Inhalation exposure was monitored using personal air pumps and XAD-2 sampling tubes. For the monitoring of hand exposure, cotton gloves were used in two trials and rubber gloves in another three. The total volumes of spray solution contaminating the body of the operator were 25.37 and 35.83 ml/h, corresponding to 0.05 and 0.07% of the applied spray solution, respectively, in the case of low pressure knapsack applications and from 160.76 to 283.45 ml/h, corresponding to 0.09-0.19% of the spray solution applied, in the case of hand lance applications with tractor-generated high pressure. Counts on gloves depended on the absorbance/repellency of the glove material. The potential inhalation exposures were estimated at 0.07 and 0.09 ml/h in the case of low pressure knapsack applications, based on a ventilation rate of 25 l/min. Both potential dermal operator exposure (excluding hands) and potential inhalation exposure were increased by a factor of approximately 7 when the application pressure was increased from 3 to 18 bar in greenhouse trials with a tractor-assisted hand lance, the rest of the application conditions being very similar.
[1]
G Chester,et al.
Evaluation of agricultural worker exposure to, and absorption of, pesticides.
,
1993,
The Annals of occupational hygiene.
[2]
H. N. Nigg,et al.
Pesticide exposure to a greenhouse drencher
,
1989,
Bulletin of environmental contamination and toxicology.
[3]
W. F. Durham,et al.
Measurement of the exposure of workers to pesticides.
,
1962,
Bulletin of the World Health Organization.
[4]
J. J. van Hemmen,et al.
PREDICTIVE EXPOSURE MODELLING FOR PESTICIDE REGISTRATION PURPOSES
,
1993
.
[5]
E Capri,et al.
Potential operator exposure to procymidone in greenhouses.
,
1999,
Journal of agricultural and food chemistry.
[6]
Kyriaki Machera,et al.
EVALUATION OF POTENTIAL DERMAL EXPOSURE OF PESTICIDE SPRAY OPERATORS IN GREENHOUSES BY USE OF VISIBLE TRACERS
,
2002,
Journal of environmental science and health. Part. B, Pesticides, food contaminants, and agricultural wastes.
[7]
J. V. van Hemmen.
Predictive exposure modelling for pesticide registration purposes.
,
1993,
The Annals of occupational hygiene.