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THIRD
WORLD NETWORK INFORMATION SERVICE ON SUSTAINABLE AGRICULTURE Dear Friends and Colleagues Pesticides Found to Be Extensively Detrimental to Soil Organisms A single handful of soil contains a huge diversity of anywhere between 10 and 100 million organisms and they all have important roles to play in the function of healthy soil such as nutrient cycling, soil structure maintenance, the regulation of pests and diseases, and carbon sequestration. Pesticides are often applied directly to soil as drenches and granules and increasingly in the form of seed coatings. A comprehensive review of the impacts of agricultural pesticides on soil invertebrates has found that pesticide exposure negatively impacted soil invertebrates in 70.5% of 2,842 tested parameters. Nearly 400 studies were reviewed, involving 284 different pesticide active ingredients. The review found that all classes of pesticides pose a clear hazard to soil invertebrates傭y killing them, reducing reproduction and species diversity, impacting growth and cellular function, or other negative impacts. Insecticides had a negative impact on over 60% of the tested parameters in the field studies, followed by bactericides at 50% and fungicides around 40%. For tested parameters involving mixtures of pesticides, the negative impact was found in 55%. The organisms most negatively impacted by pesticide use were ground-nesting bees and parasitic wasps that provide natural pest control. This review underscores the need for soil organisms to be represented in any risk analysis of a pesticide that has the potential to contaminate soil, and for any significant risk to be mitigated in a way that will specifically reduce harm to soil organisms and to the many important ecosystem functions they provide. The authors therefore call for the inclusion of a soil health analysis in the pesticide risk assessment process. With best wishes, Third
World Network 覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧・ Item 1 PESTICIDES AND SOIL INVERTEBRATES: A HAZARD ASSESSMENT Gunstone,
T. et al. Abstract Agricultural pesticide use and its associated environmental harms is widespread throughout much of the world. Efforts to mitigate this harm have largely been focused on reducing pesticide contamination of the water and air, as runoff and pesticide drift are the most significant sources of offsite pesticide movement. Yet pesticide contamination of the soil can also result in environmental harm. Pesticides are often applied directly to soil as drenches and granules and increasingly in the form of seed coatings, making it important to understand how pesticides impact soil ecosystems. Soils contain an abundance of biologically diverse organisms that perform many important functions such as nutrient cycling, soil structure maintenance, carbon transformation, and the regulation of pests and diseases. Many terrestrial invertebrates have declined in recent decades. Habitat loss and agrichemical pollution due to agricultural intensification have been identified as major driving factors. Here, we review nearly 400 studies on the effects of pesticides on non-target invertebrates that have egg, larval, or immature development in the soil. This review encompasses 275 unique species, taxa or combined taxa of soil organisms and 284 different pesticide active ingredients or unique mixtures of active ingredients. We identified and extracted relevant data in relation to the following endpoints: mortality, abundance, biomass, behavior, reproduction, biochemical biomarkers, growth, richness and diversity, and structural changes. This resulted in an analysis of over 2,800 separate 鍍ested parameters,・measured as a change in a specific endpoint following exposure of a specific organism to a specific pesticide. We found that 70.5% of tested parameters showed negative effects, whereas 1.4% and 28.1% of tested parameters showed positive or no significant effects from pesticide exposure, respectively. In addition, we discuss general effect trends among pesticide classes, taxa, and endpoints, as well as data gaps. Our review indicates that pesticides of all types pose a clear hazard to soil invertebrates. Negative effects are evident in both lab and field studies, across all studied pesticide classes, and in a wide variety of soil organisms and endpoints. The prevalence of negative effects in our results underscores the need for soil organisms to be represented in any risk analysis of a pesticide that has the potential to contaminate soil, and for any significant risk to be mitigated in a way that will specifically reduce harm to soil organisms and to the many important ecosystem services they provide. 覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧覧蘭 Item 2 NEW STUDY SHOWS PESTICIDES・HARMFUL IMPACTS ON SOIL ORGANISMS Becca
Lucas A recent study published in the journal Frontiers in Environmental Science illuminates the connection between pesticide use and decreased soil microbial and organism activity, which has detrimental implications for soil ecosystems, soil carbon storage, and the environment at large. In recent years and especially now, during Pollinator Week 2021, there has been much attention paid to the impact of pesticides on honeybees, as these important pollinators have been increasingly threatened by the spraying of neonicotinoid insecticides. Air and water quality effects from pesticide use, as runoff and drift can impact communities in agricultural areas are also discussed widely, but there has been less focus on the detrimental effect pesticide use can have on soil health. This comprehensive study makes this connection clear. Background A joint project with Friends of the Earth, Center for Biological Diversity and researchers at the University of Maryland, this meta-analysis involved a systematic review of nearly 400 studies that examined the impact of pesticides on non-target invertebrates, that is, not the pests that the pesticide is seeking to eliminate. These studies covered 284 different pesticides or combinations of pesticides used in the field and laboratory settings and 275 unique species of soil invertebrates. Pesticides is an umbrella term that includes insecticides, herbicides, fungicides, bactericides容ssentially all agents that have the purposes of eliminating a pest that threatens crops, through either competition for nutrients and/or water (like weeds) or direct harm to the plants (like specific insects). Pesticides can enter the soil in several ways: by seeping into it when they are applied as granules, coated seeds, or through irrigation systems (a process referred to as fertigation), or when crop residues from plants treated with pesticides decompose in fields. A single handful of soil contains a huge diversity of anywhere between 10 and 100 million organisms and they all have an important role to play in the function of healthy soil. For the purposes of this study, soil invertebrates were identified as any organism 鍍hat has egg, larval or immature development in the soil,・including bacteria, fungi, and invertebrates such as worms, mites, beetles, ants, centipedes, centipedes, millipedes, termites, slugs, snails and more. What did the study find? The study ultimately found that in the 284 existing studies, all classes of pesticides posed a threat to these soil invertebrates傭y killing them, reducing reproduction and species diversity, impacting growth and cellular function, or other negative impacts. To come to this conclusion, the researchers studied over 2,800 鍍ested parameters・ which they defined as unique combinations of each pesticides impact on each soil invertebrate and the resulting effect from the pesticide. Though the researchers looked at studies conducted in both lab and field settings, we are most interested in data from the field studies that are most similar to real-world situations. Overall, the researchers found that in field settings, pesticides had a negative impact on over 50% of tested parameters. Insecticides had a negative impact on over 60% of the tested parameters in the field studies, followed by bactericides at 50% and fungicides around 40%. For tested parameters involving mixtures of pesticides, the negative impact was found in 55%. Insecticides were also the most-studied type of pesticide and as the study points out, this majority negative impact is not surprising as the pesticide is specifically designed to eliminate invertebrates indiscriminately, regardless of whether they are crop pests or provide environmental and agronomic benefits. The organisms most negatively impacted by pesticide use were ground-nesting bees and parasitic wasps that provide natural pest control. Across all the pesticides examined in field studies, the most commonly caused negative impacts were on biochemical biomarkers葉hat is, any biochemical or molecular response from exposure to the toxins, like gene expression, metabolism. Invertebrate death and changes in behavior were the next most common issues due to pesticide exposure in the field. Why do soil invertebrates matter? These soil invertebrates help with overall soil health. Earthworms and other diggers support soil structure and water infiltration by digging tunnels and galleries underground, creating room for other smaller invertebrates and allowing water to not only infiltrate more quickly, but also be stored in the soil. Some invertebrates provide natural pest regulation that can lead to fewer chemical inputs, like ladybugs who eat aphids or soil insects who eat undesired seeds, providing weed control. These soil organisms also aid in the process of carbon sequestration by increasing soil organic matter, a result of them eating plant residues and other underground detritus. This means that soil invertebrates, while perhaps uncelebrated, play a direct role in mitigating climate change impacts by helping develop healthy soils. The life and wellness of soil organisms, and their critical contribution to addressing the climate crisis, can be protected by reducing or eliminating the use of synthetic pesticides・practices commonly associated with sustainable and organic practices.
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