Using biological traits to predict species sensitivity to toxic substances.
about
Biological and ecological traits of marine species.The pros and cons of ecological risk assessment based on data from different levels of biological organizationTraits-based approaches in bioassessment and ecological risk assessment: strengths, weaknesses, opportunities and threats.Pharmaceuticals in biota in the aquatic environment: analytical methods and environmental implications.Advancing In Vitro-In Vivo Extrapolations of Mechanism-Specific Toxicity Data Through Toxicokinetic Modeling.Toward a knowledge infrastructure for traits-based ecological risk assessment.A plea for the use of copepods in freshwater ecotoxicology.Development and application of the SSD approach in scientific case studies for ecological risk assessment.Toward refined environmental scenarios for ecological risk assessment of down-the-drain chemicals in freshwater environments.Species traits as predictors for intrinsic sensitivity of aquatic invertebrates to the insecticide chlorpyrifos.Effect of thiram and of a hydrocarbon mixture on freshwater macroinvertebrate communities in outdoor stream and pond mesocosms: II. Biological and ecological trait responses and leaf litter breakdown.Evaluating aquatic invertebrate vulnerability to insecticides based on intrinsic sensitivity, biological traits, and toxic mode of action.Derivation of water quality criteria of phenanthrene using interspecies correlation estimation models for aquatic life in China.Sensitivity of animals to chemical compounds links to metabolic rate.Comparison of species sensitivity distributions based on population or individual endpoints.Augmenting aquatic species sensitivity distributions with interspecies toxicity estimation models.Sensitivity assessment of freshwater macroinvertebrates to pesticides using biological traits.Capturing ecology in modeling approaches applied to environmental risk assessment of endocrine active chemicals in fish.A comparison of the sublethal and lethal toxicity of four pesticides in Hyalella azteca and Chironomus dilutus.Improvement on species sensitivity distribution methods for deriving site-specific water quality criteria.Guidance on tiered risk assessment for plant protection products for aquatic organisms in edge-of-field surface watersPhysiological sensitivity of freshwater macroinvertebrates to heavy metals.Traits-based ecological risk assessment (TERA): realizing the potential of ecoinformatics approaches in ecotoxicology.Competing statistical methods for the fitting of normal species sensitivity distributions: recommendations for practitioners.Framework for traits-based assessment in ecotoxicology.Extensive gaps and biases in our knowledge of a well-known fauna: implications for integrating biological traits into macroecologyUsing phylogenetic information to predict species tolerances to toxic chemicalsRelative Sensitivity Distribution of Freshwater Planktonic Crustaceans to Trace MetalsIs it possible to extrapolate results of aquatic microcosm and mesocosm experiments with pesticides between climate zones in Europe?
P2860
Q28608489-83F5BC04-9E7E-4117-A72C-4E99B256ACD8Q31110434-669E912D-94AB-4438-88DE-F56B890A09F9Q33730465-5515B093-021D-4CA8-95BD-A4AED8905912Q34296925-3A30E86D-4D94-46DC-8D2E-04A51DD77295Q36130508-9518093E-062D-4780-8B10-3ACB7BA10612Q37858490-DEFC386E-E45E-4646-A499-914A77A72714Q38035221-EFB645A7-DB0C-4889-8337-CCD299D87838Q38825204-600F7A68-8CFC-4E05-8E4A-1CFCDC1C3BE6Q38853447-F37CEAB0-B186-487A-91D2-D1020509ED16Q39600275-E53B3C5C-08F7-4E41-B1D0-A09E1534ABF7Q40603678-97258EE9-4E09-4DA4-BB6C-B55FAD54140EQ41100620-67E4CF25-200A-4857-8D25-A24C6BD40D37Q41548456-26899700-3B97-4BE1-8136-9D9BCA046259Q41617216-5CE3EF71-10F1-4ECE-A7FD-5437E470F379Q43837380-DCBAC76D-035C-42C4-8BF2-2B7863A219BCQ44223648-A6CF60F9-28F0-4B22-9662-97A193A40C49Q45353497-EC61516A-875F-4E9E-A173-0499FF6ADABCQ46304054-3C13334A-8EF9-4EEA-8C39-8BC837E7A6BBQ46483759-B827DE91-9ED7-41B0-B559-817CEA5A5F38Q46815509-26BC3C29-7D7C-42EC-B8CB-6B401A5CD306Q47153508-A4911E61-517D-40E2-8C58-DCD0D18A7F08Q47817191-94CA37D3-3197-4D22-9F96-34A685A4391CQ51174340-8E73C2D1-F38A-4E95-9A1B-6903CF1494E5Q51505247-2B290D5D-74C7-4EEE-A4B3-AE92624D8D82Q51616234-E5E28321-5496-43F9-B887-BF84B54CCB89Q57232928-85E9521B-5C4B-4205-A092-A5840B1F2C64Q58192862-53AABA12-02C5-4A2C-B469-346602515EEFQ58385333-D3FDC971-8FE7-4A03-A721-2C9CD49B0626Q58828690-17937FE6-688F-40CA-B540-504D71726B07
P2860
Using biological traits to predict species sensitivity to toxic substances.
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh-hant
name
Using biological traits to predict species sensitivity to toxic substances.
@en
Using biological traits to predict species sensitivity to toxic substances.
@nl
type
label
Using biological traits to predict species sensitivity to toxic substances.
@en
Using biological traits to predict species sensitivity to toxic substances.
@nl
prefLabel
Using biological traits to predict species sensitivity to toxic substances.
@en
Using biological traits to predict species sensitivity to toxic substances.
@nl
P1476
Using biological traits to predict species sensitivity to toxic substances.
@en
P2093
Donald J Baird
P304
P356
10.1016/J.ECOENV.2006.07.001
P577
2006-09-22T00:00:00Z