DFDT, a fast-acting insecticide, has an alarming history, researchers report.
“We set out to study the growth of crystals in a little-known insecticide and uncovered its surprising history, including the impact of World War II on the choice of DDT—and not DFDT—as a primary insecticide in the 20th century,” says Bart Kahr, professor of chemistry at New York University and one of the study’s senior authors.
Kahr and fellow chemistry professor Michael Ward study the growth of crystals, which two years ago led them to discover a new crystal form of the notorious insecticide DDT. DDT is known for its detrimental effect on the environment and wildlife, but the new form Kahr and Ward developed was more effective against insects—and in smaller amounts, potentially less harmful to the environment.
The origins of DFDT in the Third Reich
Alongside chemical analysis, the researchers uncovered a rich and unsettling backstory for DFDT. Through historical documents, they learned that German scientists created DFDT during World War II as an insecticide and that the German military used it for insect control in the Soviet Union and North Africa, in parallel with the use of DDT by American armed forces in Europe and the South Pacific.
In the post-war chaos, however, DFDT manufacturing came to an abrupt end. Allied military officials who interviewed Third Reich scientists dismissed the Germans’ claims that DFDT was faster and less toxic to mammals than DDT, calling their studies “meager” and “inadequate” in military intelligence reports.
In his 1948 Nobel Prize address for the discovery of the insect-killing capability of DDT, Paul Müller noted that DFDT should be the insecticide of the future, given that it works more quickly than does DDT. Despite this, DFDT has largely been forgotten and was unknown to contemporary entomologists with whom the researchers consulted.
“We were surprised to discover that at the outset DDT had a competitor which lost the race because of geopolitical and economic circumstances, not to mention its connection to the German military, and not necessarily because of scientific considerations. A faster, less persistent insecticide, as is DFDT, might have changed the course of the 20th century; it forces us to imagine counterfactual science histories,” says Kahr.
Swapping out atoms
In continuing to explore the crystal structure of insecticides, the research team began studying fluorinated forms of DDT, swapping out chlorine atoms for fluorine. They prepared two solid forms of the compound—a monofluoro and a difluoro analog—and tested them on fruit flies and mosquitoes, including mosquito species that carry malaria, yellow fever, Dengue, and Zika. The solid forms of fluorinated DDT killed insects more quickly than did DDT; the difluoro analog, known as DFDT, killed mosquitoes two to four times faster.
“Speed thwarts the development of resistance,” says Ward, a senior author on the study. “Insecticide crystals kill mosquitoes when they are absorbed through the pads of their feet. Effective compounds kill insects quickly, possibly before they are able to reproduce.”
The researchers also made a detailed analysis of the relative activities of the solid-state forms of fluorinated DDT, noting that less thermodynamically stable forms—in which the crystals liberate molecules more easily—were more effective at quickly killing insects.
Searching for better pesticides
Mosquito-borne diseases such as malaria—which kills a child every two minutes—are major public health concerns, resulting in 200 million illnesses annually. Newer diseases like Zika may pose growing threats to health in the face of a changing climate.
Mosquitoes are increasingly resistant and are failing to respond to the pyrethroid insecticides built into bed nets. Public health officials are concerned and have reconsidered the use of DDT—which has been banned for decades in much of the world with the exception of selective use for malaria control—but its controversial history and environmental impact encourage the need for new insecticides.
“While more research is needed to better understand the safety and environmental impact of DFDT, we, along with the World Health Organization, recognize the urgent need for new, fast insecticides. Not only are fast-acting insecticides critical for fighting the development of resistance, but less insecticide can be used, potentially reducing its environmental impact,” says Ward.
The study appears in the Journal of the American Chemical Society.
Additional researchers from NYU and Arrowhead Pharma contributed to the work. Support for the work came from the NYU Materials Research Science and Engineering Center program of the National Science Foundation. The NSF partially supports the NYU X-ray facility.
Source: New York University