Understanding single‐species and model ecosystem sensitivity: Data‐based comparison

Versteeg, Donald J.; Belanger, Scott E.; Carr, Gregory J.

doi:10.1002/etc.5620180636

Cited by 99 publications

(90 citation statements)

References 109 publications

(52 reference statements)

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“…Studies of other pesticides that compared threshold concentrations for direct toxic effects as a result of chronic exposure between model ecosystem experiments are not known to us. However, evidence suggests that threshold concentrations for chronic exposure to the surfactant dodecyl trimethyl ammonium chloride do not differ much between model stream experiments (range of NOEC ecosystem values, 180-300 lg/L; n ¼ 5; Versteeg et al 1999). Similarly, only a 3-fold difference in threshold concentrations is reported for long-term exposure to copper (hardness adjusted to 50 mg/L as CaCO 3 ) derived from 1 lentic mesocosm and 6 artificial stream studies conducted in the United States and Europe (Versteeg et al 1999).…”

Section: Compoundmentioning

confidence: 99%

Aquatic Risks of Pesticides, Ecological Protection Goals, and Common Aims in European Union Legislation

Brock

Arts

Maltby

2006

Integr Environ Assess Manag

121

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This discussion paper presents a framework for spatiotemporal differentiation in ecological protection goals to assess the risks of pesticides in surface waters. It also provides a proposal to harmonize the different scientific approaches for ecotoxicological effect assessment adopted in guidance documents that support different legislative directives in the European Union (Water Framework Directive and Uniform Principles). Decision schemes to derive maximum permissible concentrations in surface water are presented. These schemes are based on approaches recommended in regulatory guidance documents and are scientifically underpinned by critical review papers concerning the impact of pesticides on freshwater organisms and communities. Special attention is given to the approaches based on standard test species, species sensitivity distribution curves, and model ecosystem experiments. The decision schemes presented here may play a role in the ''acceptability'' debate and can be used as options in the process of communication between risk assessors and risk managers as well as between these risk experts and other stakeholders.

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Section: Compoundmentioning

confidence: 99%

Aquatic Risks of Pesticides, Ecological Protection Goals, and Common Aims in European Union Legislation

Brock

Arts

Maltby

2006

Integr Environ Assess Manag

121

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“…Risk assessment of toxic compounds released to the aquatic environment is mostly based on results extrapolated from single-species (SS) laboratory tests using algae, daphnids, and "sh (e.g., Rand and Petrocelli, 1985;OECD, 1992;Zeeman and Gilford, 1993;Forbes and Forbes, 1993;van Leeuwen, 1996b), where the measured endpoints generally include survival, growth, and reproduction (Versteeg et al, 1999). Available toxicity data may include L(E)C , which is the concentration of toxicant that causes lethality (L) or e!ect (E) in 50% of an exposed population, or the concentration in a concentration}response experiment that does not cause a stastically detectable e!ect: no-observede!ect concentration (NOEC).…”

Section: Levelmentioning

confidence: 99%

“…The most commonly used distribution models assume a log-normal (Wagner and L+kke, 1991) or log-logistic (Aldenberg and Slob, 1993) distribution of NOEC values for di!erent species. Several biological and statistical assumptions are implied in the SSD models to make the extrapolation from laboratory tests to e!ects at the ecosystem level including the assumptions that (1) the variability in the sensitivity of the laboratory test species is similar to the variability among the species for which one aims to assess risk, (2) the endpoints measured in laboratory tests are indicative of e!ects on populations in the "eld, and (3) the estimated toxicant concentration, at which the NOECs of, generally, 95% of the species are not exceeded, protects ecosystem structure and function to an appropriate degree (Versteeg et al, 1999). However, in practice neither the assessment factor approach nor the SSD approach consistently ful"lls these assumptions (Forbes and Calow, 2002).…”

Section: Levelmentioning

confidence: 99%

Comparing Sensitivity of Ecotoxicological Effect Endpoints between Laboratory and Field

Selck

Riemann²,

Christoffersen

et al. 2002

Ecotoxicology and Environmental Safety

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“…For decades, P&G has worked collaboratively with government, academic, and other industry scientists to develop the methods and assessments to understand and improve both the environmental safety, and life cycles of products that people use every day (Bradbury et al 2004;Cowan et al 1995;Cowan-Ellsberry et al 2004;de Koning et al 2010;Fava et al 1991;Pittinger et al 1991;Saouter et al 2002;van de Plassche et al 1999;Versteeg et al 1999 Fava et al 1990;Franklin and Ltd 1992;Lentz et al 1989;MRI Project No. 3746-D 1974;Nylander 1991;Sandgren 1993;Sauer et al 1994;UK Environment Agency 2005, 2008Vizcarra et al 1994).…”

Section: Introductionmentioning

confidence: 99%

LCA-measured environmental improvements in Pampers® diapers

Weisbrod

Hoof

2011

Int J Life Cycle Assess

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Understanding single‐species and model ecosystem sensitivity: Data‐based comparison

Cited by 99 publications

References 109 publications

Aquatic Risks of Pesticides, Ecological Protection Goals, and Common Aims in European Union Legislation

Aquatic Risks of Pesticides, Ecological Protection Goals, and Common Aims in European Union Legislation

Comparing Sensitivity of Ecotoxicological Effect Endpoints between Laboratory and Field

LCA-measured environmental improvements in Pampers® diapers

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