Pesticides wildlife exposure

Biological sampling determining routes of wildlife exposure to pesticides... 

The first step in a wildlife exposure assessment is to document the occurrence and persistence of a pesticide in the study area throughout the study duration. Several articles in this book describe the experimental designs and best practices to conduct field crop and environmental dissipation (air, soil and water) studies. This article presents methods to quantify spatial and temporal distributions of pesticide presence in ecosystems following normal application and resultant exposure of nontarget wildlife. 

For the purposes of these field studies, a test system is defined as a specific tract of land managed in part through use of pesticides. Test systems are normally limited to one crop or land use type and may include row crops, grains, fruits or golf courses. The tract of land, of course, has associated biota that are present naturally or as part of the management practices. These biota are also part of the test system and are normally described as test species or species of interest. Selection of test systems is critical to evaluate wildlife exposure scenarios in a sufficient number of sites within appropriate geographic regions. 

Hardy, A.R. (1990). Estimating exposure The identification of species at risk and routes of exposure. In L. Somerville and C.H. Walker (Eds.) Pesticide Effects on Terrestrial Wildlife, 81-98, London Taylor Francis. 

Studies may be designed for estimating exposures to a wide array of wildlife, including birds, mammals and amphibians. Many regulatory requirements involve birds, and less emphasis is currently placed on other species. As regulatory requirements evolve, ecological risk assessments will be required for more species. This may require alternative approaches for food item analysis to allow estimates of pesticide ingestion. 

G.P. Cobb and M. J. Hooper, Nonlethal wildlife monitoring to determine exposure to xenobiotics and resulting impacts, in The Population Ecology and Wildlife Toxicology of Agricultural Pesticide Use, eds. R.J. KendaU and TE. Lacher, Lewis Pubhshers, Chelsea, MI, pp. 35-46 (1994). 

Pharmacologically, carbofuran inhibits cholinesterase, resulting in stimulation of the central, parasympathetic, and somatic motor systems. Sensitive biochemical tests have been developed to measure cholinesterase inhibition in avian and mammalian brain and plasma samples and are useful in the forensic assessment of carbamate exposure in human and wildlife pesticide incidents (Bal-lantyne and Marrs Hunt and Hooper 1993). Acute toxic clinical effects resulting from carbofuran exposure in animals and humans appear to be completely reversible and have been successfully treated with atropine sulfate. However, treatment should occur as soon as possible after exposure because acute carbofuran toxicosis can be fatal younger age groups of various species are more susceptible than adults (Finlayson et al. 1979). Carbofuran labels indicate that application is forbidden to streams, lakes, or ponds. In addition, manufacturers have stated that carbofuran is poisonous if swallowed, inhaled, or absorbed through the skin. Users are cautioned not to breathe carbofuran dust, fumes, or spray mist and treated areas should be avoided for at least 2 days (Anonymous 1971). Three points are emphasized at this juncture. First, some carbofuran degradation... 

Humans can be exposed to POPs through diet, occupational exposures (for example, farmworkers may be exposed to POPs through pesticides), industrial accidents and the environment (including indoor exposure). Exposure to POPs, either acute or chronic, can be associated with a wide range of adverse health effects, including illness and death (L. Ritter et al., 1995). Laboratory animal studies and wildlife studies have associated POPs with endocrine disruption, reproductive and immune dysfunction, neurobehavioral disorders and cancer. More recently, some POPs have also been connected to reduced immunity in infants and children and a concomitant increase in infections. Other studies have linked POPS concentrations in humans with developmental abnormalities, neurobehavioral impairment and cancer and tumor induction or promotion.4... 

Pesticide registrants must also submit environmental fate and effects data to the EPA as part of an application for pesticide registration. The EPA uses such environmental data to characterize the persistence and partitioning of a pesticide in the environment and the pesticide s environmental metabolites and degradates. This information is used by the EPA to assess the potential for human exposure via drinking water contamination and environmental exposure of organisms such as fish, wildlife, and plants to the pesticide or its metabolites. 

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