31 March 2009 Cornell University

New Method Applies Pesticides in Nanofibres to Keep Chemicals on Target

To prevent pesticides from drifting away and potentially posing risks to the environment, Cornell researchers have devised a solution: Apply the pesticides by encapsulating them in biodegradable nanofibres, which keeps then intact until needed and minimizes loss to drift or being washed away from the plants they are intended to protect.

To find out if pesticides delivered this way could really work, professor Michael Hoffmann's entomology group planted 4-by-4 millimeter squares of pesticide-loaded fabrics with pole bean seeds.

To find out if pesticides delivered this way could really work, professor Michael Hoffmann's entomology group planted 4-by-4 millimeter squares of pesticide-loaded fabrics with pole bean seeds

"Our technology will decrease the amount of pesticides applied, which is good for the environment," said research associate Chunhui Xiang, Ph.D. '08, who worked on the new technology with Margaret Frey, associate professor of fiber science and apparel design in the College of Human Ecology, as well as Cornell experts in horticultural sciences and entomology. "All the materials are biodegradable and from renewable resources."

The new technology also extends how long the pesticides remain effective and improves the safety of applications. As the fibre biodegrades, the chemicals are slowly released into the soil.

Xiang, who was named the outstanding student of the American Chemical Society Division for Cellulose and Renewable Materials last year, presented the material at the American Chemical Society annual meeting, March 22-26, in Salt Lake City .

"The chemical is protected, so it won't degrade from being exposed to air and water," Frey said. "It also keeps the chemical where it needs to be and allows it to time-release."

The delivery system is created by electrospinning solutions of cellulose, the pesticide and PLA -- a polymer derived from cornstarch.

For the initial trials, Xiang measured chemical delivery in the laboratory over a 16-week period. The individual fibers tested had a diameter more than 100 times finer than a human hair and could hold up to 50 percent of their weight in agricultural chemicals. The results showed that the chemical was released gradually over the entire four-month period, and that the rate of release could be adjusted by changing the composition of the fiber. The chemical itself did not degrade.

To find out if pesticides delivered this way could really work, professor Michael Hoffmann's entomology group planted 4-by-4 millimeter squares of pesticide-loaded fabrics with pole bean seeds in greenhouses on campus. Pesticide delivered from the fabric effectively controlled white flies on the bean plants.

Meanwhile, professor Alan Taylor's group in horticultural science is investigating use of these fibers to deliver pesticides with seed coating technologies. The team is also considering this system for direct application to plant leaves or stalks.

"It's the tip of the iceberg," Frey said.

This research is funded in part by federal Hatch funds, administered by the Cornell University Agricultural Experiment Station.

Sheri Hall is assistant communications director for the College of Human Ecology .

Source: www.news.cornell /...


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