posted on 2019-10-07, 20:29authored byXiaolong Zhu, Chunhua T. Hu, Jingxiang Yang, Leo A. Joyce, Mengdi Qiu, Michael D. Ward, Bart Kahr
Malaria control is under threat by
the development of vector resistance
to pyrethroids in long-lasting insecticidal nets, which has prompted
calls for a return to the notorious crystalline contact insecticide
DDT. A faster acting difluoro congener, DFDT, was developed in Germany
during World War II, but in 1945 Allied inspectors dismissed its superior
performance and reduced toxicity to mammals. It vanished from public
health considerations. Herein, we report the discovery of amorphous
and crystalline forms of DFDT and a mono-fluorinated chiral congener,
MFDT. These solid forms were evaluated against Drosophila as well as Anopheles and Aedes mosquitoes, the former identified as disease vectors for malaria
and the latter for Zika, yellow fever, dengue, and chikungunya. Contact
insecticides are transmitted to the insect when its feet contact the
solid surface of the insecticide, resulting in absorption of the active
agent. Crystalline DFDT and MFDT were much faster killers than DDT,
and their amorphous forms were even faster. The speed of action (a.k.a.
knockdown time), which is critical to mitigating vector resistance,
depends inversely on the thermodynamic stability of the solid form.
Furthermore, one enantiomer of the chiral MFDT exhibits faster knockdown
speeds than the other, demonstrating chiral discrimination during
the uptake of the insecticide or when binding at the sodium channel,
the presumed destination of the neurotoxin. These observations demonstrate
an unambiguous link between thermodynamic stability and knockdown
time for important disease vectors, suggesting that manipulation of
the solid-state chemistry of contact insecticides, demonstrated here
for DFDT and MFDT, is a viable strategy for mitigating insect-borne
diseases, with an accompanying benefit of reducing environmental impact.