H/t reader squodgy:
“Perhaps the people where it originates will now wake up as evidence increases they are being slowly killed by the big corporate enterprises in the name of free enterprise and capitalism, when it is really just the other end of the circle…communism and capitalism lead to the same end….domination of the many by the few. Enjoy.”
According to new research from University of Virginia in the U.S., widespread adoption of genetically modified (GM) crops has decreased the use of insecticides, but increased the use of weed-killing herbicides as weeds become more resistant, leading to serious environmental damage.
Economist Federico Ciliberto led the largest study of genetically modified crops and pesticide use to date, alongside Edward D. Perry of Kansas State University, David A. Hennessy of Michigan State University and GianCarlo Moschini of Iowa State University. The four economists studied annual data from more than 5,000 soybean and 5,000 maize farmers in the U.S. from 1998 to 2011, far exceeding previous studies that have been limited to one or two years of data.
Herbicide Use / Environmental Impact (EIQ)
“The fact that we have 14 years of farm-level data from farmers all over the U.S. makes this study very special,” Ciliberto said. “We have repeated observations of the same farmers and can see when they adopted genetically modified seeds and how that changed their use of chemicals.”
Since 2008, genetically engineered crops have accounted for more than 80 percent of maize and soybean crops planted in the U.S. Maize seeds are modified with two genes: one kills insects that eat the seed and one allows the seed to tolerate glyphosate, a herbicide commonly used in weed killers like Roundup. Soybeans are modified with just one glyphosate-resistant gene.
Unsurprisingly, maize farmers who used the insect-resistant seeds used significantly less insecticide – about 11.2 percent less – than farmers who did not use genetically modified maize. The maize farmers also used 1.3 percent less herbicide over the 13-year period.
Soybean crops, on the other hand, saw a significant increase in herbicide use, with adopters of genetically modified crops using 28 percent more herbicides than non-adopters.
Ciliberto attributes this increase to the proliferation of glyphosate-resistant weeds.
Commentators and other peer-reviewed studies have even stated that the rise in pesticide use on GM crops has gone up much further since the 1998-2011 data that was reviewed in this new University of Virginia study. The period from 2011-2016 is when glyphosate-resistant weeds have become a major economic problem for U.S. farmers based on the increase of use and thus money spent on pesticides cutting in to their bottom line.
THE GLYPHOSATE BOX
“In the beginning, there was a reduction in herbicide use, but over time the use of chemicals increased because farmers were having to add new chemicals as weeds developed a resistance to glyphosate,” Ciliberto said.
Maize farmers, he said, have not yet had to address the same level of resistance, in part because they did not adopt genetically modified crops as quickly as their counterparts in the soy industry. However, the study did find evidence that both maize and soybean farmers increased herbicide use during the last five years of the study, indicating that weed resistance is a growing problem for both groups.
From 2006 to 2011, the percentage of hectares sprayed with only glyphosate shrunk from more than 70 percent to 41 percent for soybean farmers and from more than 40 percent to 19 percent for maize farmers. The decrease resulted from farmers having to resort to combining glyphosate herbicides with other chemicals as glyphosate-resistant weeds became more common.
“Evidence suggests that weeds are becoming more resistant and farmers are having to use additional chemicals, and more of them,” Ciliberto said.
Insects do not appear to have developed a similar resistance, in part because federal regulations require farmers to have a “safe haven” in their fields that is free of genetically modified crops. Insects and worms in those safe havens have no need to develop resistance, and because they interact and breed with insects in other parts of the field, they help prevent the development of resistant genes.
Despite the decrease in insecticide use, continued growth in herbicide use poses a significant environmental problem as large doses of the chemicals can harm biodiversity and increase water and air pollution.
Ciliberto and his colleagues measured the overall environmental impact of the changes in chemical use that have resulted from the adoption of genetically modified crops, using a measure called the environmental impact quotient, or EIQ, to account for chemicals’ impact on farmworkers, consumers and the environment. Comparing adopters to non-adopters, they found little change in the impact on farmworkers and consumers. However, the adoption of genetically modified soybeans correlated with a massive negative impacton the environment as increased herbicide use also increased contamination of local ecosystems.
Further investigation of the environmental impact quotient (EIQ) finding is now being called for by independent scientists in the U.S. and Europe using the even more accurate Pesticide Risk Tool (PRiME).
Overall, Ciliberto said he was surprised by the extent to which herbicide use had increased and concerned about the potential environmental impact.
“I did not expect to see such a strong pattern,” he concluded.
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