Toxicodynamics of malaoxon in house flies

Abstract

The fate of malaoxon was studied in a susceptible and a resistant strain of house fly following topical application. Sublethal doses were used: 160 pmol for the S-strain (0.17 × LD 50) and 1570 pmol for the R-strain (0.1 × LD 50). The penetration rates are dose dependent and semilog plots of the external amount vs time show that these rates are not proportional to this external amount. Internal concentrations of malaoxon rapidly increase following administration, reach maximum values between 30 min and 2 hr (depending on dose), and then slowly decrease. The rate of metabolic degradation is highest in the early stage of the intoxication process. A three-compartment pharmacokinetic model is postulated to explain the experimental data quantitatively. The first compartment represents external malaoxon, the other two represent internal parent compound. Statistical analysis shows that the penetration rate is better described with a sum of two exponentials rather than with a single exponential decay. In the model, degradation occurs in the first internal compartment and is assumed to be first order. Malaoxon is distributed between the two internal compartments slowly with first-order kinetics. Parameter estimation with curve-fitting procedures for the internal processes (degradation and exchange) shows that there is not one set of parameter values that can be used for both strains simultaneously. This prompted a study of possible interstrain differences in degradation capacities. It was found that in vitro the R-strain had a fourfold higher oxidative breakdown rate of malaoxon. Taking this difference into account it is possible to explain the two sets of data with one kinetic model, although other alternatives cannot be excluded.