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Relevance of generic and site-specific species sensitivity distributions in the current risk assessment procedures for copper and zinc
Bossuyt, B.T.A.; Muyssen, B.T.A.; Janssen, C.R. (2005). Relevance of generic and site-specific species sensitivity distributions in the current risk assessment procedures for copper and zinc. Environ. Toxicol. Chem. 24(2): 470-478. https://dx.doi.org/10.1897/03-067R.1
In: Environmental Toxicology and Chemistry. Setac Press: New York. ISSN 0730-7268; e-ISSN 1552-8618, more
Peer reviewed article  
Available in  Authors 
Keywords
    Chemical elements > Metals > Heavy metals > Zinc
    Chemical elements > Metals > Transition elements > Heavy metals > Copper
    Community
    Heavy metals
    Risk analysis
    Spatial distribution
    Toxicology > Ecotoxicology
    Arthropoda [WoRMS]; Branchiopoda [WoRMS]; Diplostraca [WoRMS]; Crustacea [WoRMS]; Invertebrata
    Fresh water
Authors  Top 
  • Bossuyt, B.T.A., more
  • Muyssen, B.T.A., more
  • Janssen, C.R., more
Abstract
    Species sensitivity distributions (SSD) were constructed using acute toxicity data of various cladoceran species collected in five different aquatic systems. The aim of this research was to study the relative acute cladoceran community sensitivity in different aquatic systems. Current risk assessment procedures are based upon hypothetical communities and do not take into account variation in species composition and tolerance between aquatic communities. Two metals, copper and zinc, were used as model toxicants. To establish comparative sensitivity, a standard medium (International Organization for Standardization [ISO]) was used. The generic SSD (log-normal distribution) based on toxicity data obtained in this standard medium for all species (collected at all sites) resulted in a hazardous concentrations that protects 95% of the species occurring in a (hypothetical) ecosystem (i.e., hazardous concentration protecting 95% of the species of the hypothetical ecosystem [HC5]) of 6.7 μg Cu L-1 (90% confidence limits: 4.2-10.8) and 559 μg Zn L-1 (375-843). This generic SSD was not significantly different from the site-specific SSDs (i.e., constructed with species only occurring at a specific site). Mean community sensitivity (the geometric mean of 48-h 50% effective concentration [EC50] values of species within a community) among sites varied within a factor of 2 (between 17.3 and 23.6 μg Cu L-1 for Cu and between 973 and 1,808 tag Zn L-1 for Zn), and HC5s varied within a factor of 4 for copper (between 4.5 and 17.3 μg Cu L-1) and 7 for zinc (between 194 and 1,341 μg Zn L-1). For copper, the HC50 of our generic SSD was significantly lower than the one based on literature toxicity data of cladoceran species (which were recalculated to the hardness of our standard medium). In contrast, no significant differences were observed between the generic SSD and the literature-based SSD for zinc. It is suggested that the community sensitivity of different cladoceran populations is similar among aquatic systems and is not dependent on the species composition.
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