ABSTRACT
Two derivatives of dillapiole, dillapiole ethyl ether (1KL39-B) and butyl ether-n dillapiole (1KL43-C), were studied for their toxicity and genotoxicity against Aedes albopictus, to help develop new strategies for the control of this potential vector of dengue and other arboviruses, because it is resistant to synthetic insecticides. Eggs and larvae exposed to different concentrations of 1KL39-B (25, 30, 50, 70, and 80µg/mL) and of 1KL43-C (12.5, 20, 25, 30 and 40µg/mL) exhibited toxicity and susceptibility, with 100% mortality. The LC50 was 55.86±1.57µg/mL for 1KL39-B and 25.60±1.24µg/mL for 1KL43-C, while the LC90 was 70.12µg/mL for 1KL39-B and 41.51µg/mL for 1KL43-C. The gradual decrease in oviposition of the females of the G1 to G4 generations was proportional to the increase in concentrations of these compounds, which could be related to the cumulative effect of cell anomalies in neuroblasts and oocytes (P<0.05), including micronuclei, budding, multinucleated cells and nuclear bridges. These findings showed that both 1KL39-B and 1KL43-C can serve as potential alternatives in the control of A. albopictus.
Subject(s)
Aedes/drug effects , Dioxoles/toxicity , Insecticides/toxicity , Mutagens/toxicity , Allyl Compounds , Animals , DNA Damage , Dioxoles/chemical synthesis , Female , Insecticides/chemical synthesis , Larva/drug effects , Mutagens/chemical synthesis , Oocytes/drug effects , Oviposition/drug effectsABSTRACT
The effects of two semi-synthetic dillapiole derivatives, ethyl-ether dillapiole and n-butyl ether dillapiole, on eggs and larvae of Aedes aegypti were studied in view of the need for expansion and renovation of strategic action to control this mosquito - the vector of Dengue virus -, which currently shows a high resistance to chemical insecticides. Eggs and third-instar larvae of A. aegypti that had been exposed to different concentrations of these two compounds showed toxicity and susceptibility, with 100% mortality. Classical cytogenetic assays showed genotoxicity caused by the two compounds in A. aegypti from the cumulative effect of nuclear abnormalities, indicating that these derivatives may be potential alternatives to control A. aegypti.