Chemistry Reference
In-Depth Information
Rosen, G., I. Rivera-Duarte, D.B. Chadwick, et al. 2008. Critical tissue copper residues for marine
bivalve (
Mytilus galloprovincialis
) and echinoderm (
Strongylocentrotus purpuratus
) embry-
onic development: Conceptual, regulatory and environmental implications.
Mar. Environ.
Res
. 66:327-336.
Ryan, A.C., J.R. Tomasso, and S.J. Klaine. 2009. Influence of pH, hardness, dissolved organic
carbon concentration, and dissolved organic matter source on the acute toxicity of cop-
per to
Daphnia magna
in soft waters: Implications for the biotic ligand model.
Environ.
Toxicol. Chem
. 28:1663-1670.
Ryan, A.C., E.J. Van Genderen, J.R. Tomasso, et al. 2004. Influence of natural organic mat-
ter source on copper toxicity to larval fathead minnows (
Pimephales promelas
):
Implications for the biotic ligand model.
Environ. Toxicol. Chem
. 23:1567-1574.
Santore, R.C., D.M. Di Toro, P.R. Paquin, H.E. Allen, and J.S. Meyer. 2001. Biotic ligand model
of the acute toxicity of metals. 2. Application to acute copper toxicity in freshwater fish
and
Daphnia
.
Environ. Toxicol. Chem
. 20:2397-2402.
Sappington, K.G., T.S. Bridges, S.P. Bradbury, et al. 2010. Application of the tissue residue
approach in ecological risk assessment.
Integr. Environ. Assess. Manag
. 7(1):116-140.
Sappington, K.G., T.S. Bridges, S.P. Bradbury, et al. 2011. Application of the tissue residue
approach in ecological risk assessment.
Integr. Environ. Assess. Manag
. 7:116-140.
Sarathy, V., and H.E. Allen. 2005. Copper complexation by dissolved organic matter from
surface water and wastewater effluent.
Ecotoxicol. Environ. Saf
. 61:337-344.
Schlekat, C.E., E. Van Genderen, K.A. De Schamphelaere, et al. 2010. Cross-species extrapo-
lation of chronic nickel biotic ligand models.
Sci. Total Environ
. 408:6148-6157.
Schmidt, T.S., W.H. Clements, K.A. Mitchell, et al. 2010. Development of a new toxic-unit
model for the bioassessment of metals in streams.
Environ. Toxicol. Chem
. 29:2432-2442.
Schroeder, J.E., U. Borgmann, and D.G. Dixon. 2010. Evaluation of the biotic ligand model to pre-
dict long-term toxicity of nickel to
Hyalella azteca
.
Environ. Toxicol. Chem
. 29:2498-2504.
Schwartz, M.L., and B. Vigneault. 2007. Development and validation of a chronic copper
biotic ligand model for
Ceriodaphnia dubia
.
Aquat. Toxicol
. 84:247-254.
Sciera, K.L., J.J. Isely, J.R. Tomasso Jr., et al. 2004. Influence of multiple water-quality char-
acteristics on copper toxicity to fathead minnows (
Pimephales promelas
).
Environ.
Toxicol. Chem
. 23:2900-2905.
Shoji, R. 2008. Effect of dissolved organic matter source on phytotoxicity to
Lemna aequinoctialis
.
Aquat. Toxicol
. 87:210-214.
Simpson, S.L., and G.E. Batley. 2007. Predicting metal toxicity in sediments: A critique of
current approaches.
Integr. Environ. Assess. Manag
. 3:18-31.
Slaveykova, V.I. 2007. Predicting Pb bioavailability to freshwater microalgae in the presence
of fulvic acid: Algal cell density as a variable.
Chemosphere
69:1438-1445.
Slaveykova, V.I., K. Dedieu, N. Parthasarathy, et al. 2008. Effect of competing ions
and complexing organic substances on the cadmium uptake by the soil bacterium
Sinorhizobium meliloti
.
Environ. Toxicol. Chem
. 13:1.
Slaveykova, V.I., K. Dedieu, N. Parthasarathy, et al. 2009. Effect of competing ions and
complexing organic substances on the cadmium uptake by the soil bacterium
Sinorhizobium meliloti
. Environ. Toxicol. Chem. 28:741-748.
Smolders, E., K. Oorts, P. Van Sprang, et al. 2009. Toxicity of trace metals in soil as affected
by soil type and aging after contamination: Using calibrated bioavailability models to
set ecological soil standards.
Environ. Toxicol. Chem
. 28:1633-1642.
Steenbergen, N.T., F. Iaccino, M. de Winkel, et al. 2005. Development of a biotic ligand model
and a regression model predicting acute copper toxicity to the earthworm
Aporrectodea
caliginosa
.
Environ. Sci. Technol
. 39:5694-5702.
Thakali, S., H.E. Allen, D.M. Di Toro, et al. 2006a. A terrestrial biotic ligand model. 1.
Development and application to Cu and Ni toxicities to barley root elongation in soils.
Environ. Sci. Technol
. 40:7085-7093.
