【注意事項】
* 生態影響に係る有害性情報更新日が2019年9月以前はRead-acrossデータに○を記載しておらず、被験物質が標記の物質ではない可能性がある。
**各情報源における信頼性評価スコアの定義は下記のとおりである。
| 生物種 | 学名 | 影響内容 | エンドポイント | 暴露期間(値) | 暴露期間(単位) | 毒性値 | 毒性値(単位) | 毒性値(単位)種別 | 試験中の 被験物質 濃度測定 あり:○ なし:× |
情報源 | 情報源による 信頼性評価** |
著者 | タイトル | 記載誌 | 発行年 | 情報更新日 | |||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| subject type | scientific name | effect | endpoint | exposure duration value |
exposure duration unit |
toxicity value | toxicity unit | toxicity unit type | Read-across* | QSAR | GLP | measurement of the test material |
original work type | original work reliability rank |
author | title | referenced journal | publication year | Information update date |
| 藻類 | Chlorella sorokiniana | Population/Chlorophyll A concentration | IC20 | 10 | minutes | 0.00000000102 | M | × | 16 ECOTOX | Moro,L., G. Pezzotti, M. Turemis, J. Sanchis, M. Farre, R. Denaro, M.G. Giacobbe, F. Crisafi, and M.T. Giardi | Fast Pesticide Pre-Screening in Marine Environment Using a Green Microalgae-Based Optical Bioassay | Mar. Pollut. Bull.129 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Chlorophyll | IC90 | 24 | hours | 0.018 | mg/L | × | 16 ECOTOX | Geoffroy,L., M. Couderchet, and G. Vernet | Catalase Activity of Scenedesmus obliquus as a Biomarker of Environmental Pollution by Herbicides and Copper | Meded. Fac. Landbouwwet. Rijksuniv. Gent65(2B) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | IC90 | 24 | hours | 18 | μg/L | × | 16 ECOTOX | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Mortality/Mortality | NR-LETH | 24 | hours | 2000 | μg/L | × | 16 ECOTOX | Virmani,M., J.O. Evans, and R.I. Lynn | Preliminary Studies of the Effects of S-Triazine, Carbamate, Urea, and Karbutilate Herbicides on Growth of Fresh Water Algae | Chemosphere4(2) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Physiology/Photosynthesis | EC100 | 90 | minutes | 0.02 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Chlorella sp. | Mortality/Mortality | NR-LETH | 10 | days | 400 | AI μg/L | × | 16 ECOTOX | Ukeles,R. | Growth of Pure Cultures of Marine Phytoplankton in the Presence of Toxicants | Appl. Microbiol.10 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus quadricauda | Population/Population growth rate | LC50 | 14 | days | 50 | μg/dm3 | × | 16 ECOTOX | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2) | 2020/11/16 | ||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | EC90 | 24 | hours | 0.0183699 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Mortality/Mortality | NR-LETH | 10 | days | 4 | AI μg/L | × | 16 ECOTOX | Ukeles,R. | Growth of Pure Cultures of Marine Phytoplankton in the Presence of Toxicants | Appl. Microbiol.10 | 2020/11/16 | ||||||
| 藻類 | Chlorella sp. | Mortality/Mortality | NR-LETH | Formulation | μg/L | × | 16 ECOTOX | Kvitko,K.V., B.T. Mukhamadiev, and O.V. Zalenskii | Effect of DCMU, an Inhibitor of Photophosphorylation, on the Variability of Chlorella | In: Y.S.Nasyrov (Ed.), Genet.Aspektyfotosin., Dushanbe, USSR | 2020/11/16 | ||||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | EC100 | 10 | days | 0.05 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population/Population growth rate | EC100 | 10 | days | 0.03 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus | Population/Population growth rate | LC50 | 14 | days | 50 | μg/dm3 | × | 16 ECOTOX | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Physiology/Photosynthesis | EC100 | 90 | minutes | 0.03 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Chlorophyll A concentration | IC20 | 10 | minutes | 0.00000000339 | M | × | 16 ECOTOX | Moro,L., G. Pezzotti, M. Turemis, J. Sanchis, M. Farre, R. Denaro, M.G. Giacobbe, F. Crisafi, and M.T. Giardi | Fast Pesticide Pre-Screening in Marine Environment Using a Green Microalgae-Based Optical Bioassay | Mar. Pollut. Bull.129 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | LAB | LOEC | 0.02 | hours | 5 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Eullaffroy,P., and G. Vernet | The F684/F735 Chlorophyll Fluorescence Ratio: A Potential Tool for Rapid Detection and Determination of Herbicide Phytotoxicity in Algae | Water Res.37(9): 1983-1990 | 2003 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | IC50 | 1 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3): 178-185 | 2002 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula forcipata | Population | EC50 | 4 | days | 28 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3): 184-191 | 2007 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 1 | days | 0.05 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1): 266-275 | 2011 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | NOEC | 1.7 | hours | 0.05 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | EC50 | 4 | days | 4.09 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J. | Differential Sensitivity to 30 Herbicides Among Populations of Two Green Algae Scenedesmus obliquus and Chlorella pyrenoidosa | Bull. Environ. Contam. Toxicol.68(2): 275-281 | 2002 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 12 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 21 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 3 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 6 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 1 | days | 0.04 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1): 266-275 | 2011 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 1 | days | 0.04 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1): 266-275 | 2011 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | EC50 | 4 | days | 1.3 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., W. Liang, L. Xu, S. Wang, Y. Wei, and J. Lu | Acute Toxicity of 33 Herbicides to the Green Alga Chlorella pyrenoidosa | Bull. Environ. Contam. Toxicol.66(4): 536-541 | 2001 | 2018/03/07 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | LAB | LOEC | 1 | hours | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3): 178-185 | 2002 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Mortality | 1 | days | 2000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Virmani,M., J.O. Evans, and R.I. Lynn | Preliminary Studies of the Effects of S-Triazine, Carbamate, Urea, and Karbutilate Herbicides on Growth of Fresh Water Algae | Chemosphere4(2): 65-71 | 1975 | 2018/03/15 | ||||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 1 | days | 0.03 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1): 266-275 | 2011 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 15 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus | Population | LC50 | 14 | days | 50 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus opoliensis | Physiology | LOEC | 10 | days | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1): 51-56 | 2009 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 18 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 2 | days | 14.3 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Copin,P.J., and N. Chevre | Modelling the Effects of Pulse Exposure of Several PSII Inhibitors on Two Algae | Chemosphere137:70-77 | 2015 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 3 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Physiology | NOEC | 0.25 | hours | <20 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139:65-72 | 2015 | 2018/03/15 | |||||
| 藻類 | Anabaena sp. Anabaena variabilis | Population | IC50 | 10 | days | 30 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Singh,S., P. Datta, and A. Tirkey | Response of Multiple Herbicide Resistant Strain of Diazotrophic Cyanobacterium, Anabaena variabilis, Exposed to Atrazine and DCMU | Indian J. Exp. Biol.49(4): 298-303 | 2011 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus quadricauda | Population | EC50 | 4 | days | 2.7 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., F. Lin, S. Wang, and L. Xu | Toxicity of 21 Herbicides to the Green Alga Scenedesmus quadricauda | Bull. Environ. Contam. Toxicol.71(3): 594-601 | 2003 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 9 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | IC10 | 1 | days | 4 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., M. Couderchet, and G. Vernet | Catalase Activity of Scenedesmus obliquus as a Biomarker of Environmental Pollution by Herbicides and Copper | Meded. Fac. Landbouwwet. Rijksuniv. Gent65(2B): 843-852 | 2000 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus | Population | IC50 | 1 | days | 0.057 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Grossmann,K., R. Berghaus, and G. Retzlaff | Heterotrophic Plant Cell Suspension Cultures for Monitoring Biological Activity in Agrochemical Research. Comparison with Screens Using Algae, Germinating Seeds and Whole Plants | Pestic. Sci.35(3): 283-289 | 1992 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena doliolum | Population | IC50 | 12 | days | 400 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Singh,D.P., and K. Kshatriya | Characterization of Salinity-Tolerant Mutant of Anabaena doliolum Exhibiting Multiple Stress Tolerance | Curr. Microbiol.45(3): 165-170 | 2002 | 2018/03/06 | |||||
| 藻類 | Anabaena sp. Anabaena variabilis | Population | IC50 | 10 | days | 80 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Singh,S., P. Datta, and A. Tirkey | Response of Multiple Herbicide Resistant Strain of Diazotrophic Cyanobacterium, Anabaena variabilis, Exposed to Atrazine and DCMU | Indian J. Exp. Biol.49(4): 298-303 | 2011 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | NOEC | 1 | hours | 0.005 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Biochemical | EC50 | 1 | days | 19 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Katsumata,M., T. Koike, K. Kazumura, A. Takeuchi, and Y. Sugaya | Utility of Delayed Fluorescence as Endpoint for Rapid Estimation of Effect Concentration on the Green Alga Pseudokirchneriella subcapitata | Bull. Environ. Contam. Toxicol.83(4): 484-487 | 2009 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 24 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Katsumata,M., T. Koike, K. Kazumura, A. Takeuchi, and Y. Sugaya | Utility of Delayed Fluorescence as Endpoint for Rapid Estimation of Effect Concentration on the Green Alga Pseudokirchneriella subcapitata | Bull. Environ. Contam. Toxicol.83(4): 484-487 | 2009 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | IC10 | 1 | days | 4 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3): 178-185 | 2002 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 1.7 | hours | 0.5 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | NOEC | 2 | hours | 0.005 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 4 | days | 0.02 | μmol/dm3 FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Shitanda,I., K. Takada, Y. Sakai, and T. Tatsuma | Compact Amperometric Algal Biosensors for the Evaluation of Water Toxicity | Anal. Chim. Acta530(2): 191-197 | 2005 | 2018/03/15 | ||||||
| 藻類 | Anabaena sp. Anabaena sp. | Physiology | EC50 | 1 | days | 3.78092 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139:65-72 | 2015 | 2018/03/06 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 9 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | NOEC | 6 | days | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 21 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 15 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 2 | hours | 0.05 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 12 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Physiology | LOEC | 0.25 | hours | <40 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139:65-72 | 2015 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella fusca var. vacuolata | Population | EC50 | 1 | days | 0.03 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1): 266-275 | 2011 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 1.3 | hours | 0.005 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 1.25 | days | 23000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., M.D. Hernando, L. Piedra, and Y. Chisti | Toxicity Evaluation of Single and Mixed Antifouling Biocides Measured with Acute Toxicity Bioassays | Anal. Chim. Acta456(2): 303-312 | 2002 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 5 | days | 1 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 3 | days | 10.5 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fai,P.B., A. Grant, and B. Reid | Chlorophyll a Fluorescence as a Biomarker for Rapid Toxicity Assessment | Environ. Toxicol. Chem.26(7): 1520-1531 | 2007 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 4 | days | 0.07 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 4 | days | 36.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 3 | days | 19.5 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEL | 4 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 3 | days | 15 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2017/03/15 | ||||||
| 藻類 | Scenedesmus subspicatus | Population | NOEC | 3 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2017/03/15 | ||||||
| 藻類 | Scenedesmus subspicatus | Physiology | NOEC | 1 | days | 4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC100 | 5 | days | 1 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 4 | days | 4.3 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., L. Xu, S. Wang, R. Zheng, S. Jin, S. Huang, and Y. Huang | Toxicity of 40 Herbicides to the Green Alga Chlorella vulgaris | Ecotoxicol. Environ. Saf.51(2): 128-132 | 2002 | 2017/03/15 | ||||||
| 藻類 | Scenedesmus subspicatus | Population | NOEC | 1 | days | 7 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | <100 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11): 2516-2524 | 2003 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 4 | days | 2.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 45 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2:1115-1120 | 2002 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEC | 3 | days | 9.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEL | 4 | days | 0.44 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 22.3 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 4 | days | 0.7 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., S. Wang, P. Wang, L. Ma, X. Chen, and R. Xu | Toxicity Assessment of 40 Herbicides to the Green Alga Raphidocelis subcapitata | Ecotoxicol. Environ. Saf.63(3): 456-462 | 2006 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 45 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2017/03/15 | ||||||
| 藻類 | Scenedesmus subspicatus | Population | EC50 | 3 | days | 36 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2017/03/15 | ||||||
| 藻類 | Desmodesmus subspicatus | Population | EC50 | 3 | days | 46.3 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1): 117-122 | 2011 | 2017/03/15 | ||||||
| 藻類 | Chlorella sp. Chlorella sp. | Population | LC50 | 14 | days | 40 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2017/03/15 | ||||||
| 藻類 | Desmodesmus subspicatus | Population | EC50 | 3 | days | 54 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1): 117-122 | 2011 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEL | 4 | days | 0.44 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Population | LOEC | 0.33 | hours | 0.5 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 1.3 | days | 23000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., M.D. Hernando, L. Piedra, and Y. Chisti | Toxicity Evaluation of Single and Mixed Antifouling Biocides Measured with Acute Toxicity Bioassays | Anal. Chim. Acta456(2): 303-312 | 2002 | 2018/03/16 | |||||
| 藻類 | Scenedesmus subspicatus | Population | EC50 | 1.32 | hours | 73 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nendza,M., and A. Wenzel | Discriminating Toxicant Classes by Mode of Action 1. (Eco)toxicity Profiles | Environ. Sci. Pollut. Res.13(3): 192-203 | 2006 | 2017/03/23 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 5 | days | 1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 4 | days | 0.07 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | IC10 | 4 | hours | 0.78 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | IC50 | 4 | hours | 2.6 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 3 | days | 15 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella sp. | Population | LC50 | 14 | days | 40 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEC | 0.33 | hours | 0.1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 0.33 | hours | 13.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/16 | |||||
| 藻類 | Scenedesmus subspicatus | Physiology | NOEC | 1 | days | 4 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2018/03/07 | |||||
| 藻類 | Scenedesmus subspicatus | Population | NOEC | 1 | days | 7 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2018/03/07 | |||||
| 藻類 | Scenedesmus subspicatus | Population | NOEC | 3 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2018/03/07 | |||||
| 藻類 | Desmodesmus subspicatus | Population | EC50 | 3 | days | 54 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1): 117-122 | 2011 | 2018/03/15 | |||||
| 藻類 | Scenedesmus subspicatus | Population | EC50 | 1.3 | hours | 73 | μg/L | FORMULATION,曝露期間0.82-1.32時間 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nendza,M., and A. Wenzel | Discriminating Toxicant Classes by Mode of Action 1. (Eco)toxicity Profiles | Environ. Sci. Pollut. Res.13(3): 192-203 | 2006 | 2018/03/07 | |||||
| 藻類 | Chlorella sp. Chlorella sp. | Mortality | 47000~120000 | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Kvitko,K.V., B.T. Mukhamadiev, and O.V. Zalenskii | Effect of DCMU, an Inhibitor of Photophosphorylation, on the Variability of Chlorella | In: Y.S.Nasyrov (Ed.), Genet.Aspektyfotosin., Dushanbe, USSR:255-268 | 1971 | 2018/03/15 | |||||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 3 | days | 10.5 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fai,P.B., A. Grant, and B. Reid | Chlorophyll a Fluorescence as a Biomarker for Rapid Toxicity Assessment | Environ. Toxicol. Chem.26(7): 1520-1531 | 2007 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | <100 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11): 2516-2524 | 2003 | 2018/03/16 | |||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 0.33 | hours | 27.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 45 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2:1115-1120 | 2002 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 4 | days | 4.3 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., L. Xu, S. Wang, R. Zheng, S. Jin, S. Huang, and Y. Huang | Toxicity of 40 Herbicides to the Green Alga Chlorella vulgaris | Ecotoxicol. Environ. Saf.51(2): 128-132 | 2002 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Biochemical | EC50 | 0.08 | hours | 0.01 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Naessens,M., J.C. Leclerc, and C. Tran-Minh | Fiber Optic Biosensor Using Chlorella vulgaris for Determination of Toxic Compounds | Ecotoxicol. Environ. Saf.46(2): 181-185 | 2000 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 4 | days | 0.7 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., S. Wang, P. Wang, L. Ma, X. Chen, and R. Xu | Toxicity Assessment of 40 Herbicides to the Green Alga Raphidocelis subcapitata | Ecotoxicol. Environ. Saf.63(3): 456-462 | 2006 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 45 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 22.3 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | LOEC | 4 | hours | 1.2 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEC | 3 | days | 9.4 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 0.67 | hours | 0.07 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | NOEC | 2 | hours | 0.05 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella fusca | Biochemical | IC50 | 0.25 | hours | 0.9 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Conrad,R., C. Buchel, C. Wilhelm, W. Arsalane, C. Berkaloff, and J.C. Duval | Changes in Yield of In-Vivo Fluorescence of Chlorophyll a as a Tool for Selective Herbicide Monitoring | J. Appl. Phycol.5(5): 505-516 | 1993 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula lanceolata | Population | EC50 | 6 | days | >5~<10 | FORMULATION,曝露期間4-6日間 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Roubeix,V., S. Pesce, N. Mazzella, M. Coste, and F. Delmas | Variations in Periphytic Diatom Tolerance to Agricultural Pesticides in a Contaminated River: An Analysis from Community to Population Level | In: Proceedings of the International Conference on Environmental Management, Engineering, Planning and Economics and SECOTOX Conference:343-347 | 2011 | 2018/03/16 | ||||||
| 藻類 | Scenedesmus sp. Scenedesmus opoliensis | Enzyme | NOEC | 10 | days | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1): 51-56 | 2009 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 1 | hours | 0.05 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus opoliensis | Biochemical | NOEC | 10 | days | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1): 51-56 | 2009 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus opoliensis | Biochemical | NOEC | 10 | days | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1): 51-56 | 2009 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus opoliensis | Population | LOEC | 10 | days | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1): 51-56 | 2009 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena inaequalis | Enzyme | EC50 | 0.21 | days | 1500 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Stratton,G.W., A.L. Huber, and C.T. Corke | The Effect of Pesticides and Their Metabolites, Alone and in Combination, on Algal Processes | Can. Tech. Rep. Fish. Aquat. Sci.975:131-139 | 1980 | 2018/03/06 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 2 | hours | 0.5 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 1.7 | hours | 0.005 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | LOEC | 0.67 | hours | 0.005 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Anabaena sp. Anabaena inaequalis | Population | EC50 | 2 | hours | 40 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Stratton,G.W., A.L. Huber, and C.T. Corke | The Effect of Pesticides and Their Metabolites, Alone and in Combination, on Algal Processes | Can. Tech. Rep. Fish. Aquat. Sci.975:131-139 | 1980 | 2018/03/06 | |||||
| 藻類 | Anabaena sp. Anabaena levanderi | Population | LOEL | 14 | days | 0.014 | AI kg/ha ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Perschbacher,P.W., and G.M. Ludwig | Effects of Diuron and Other Aerially Applied Cotton Herbicides and Defoliants on the Plankton Communities of Aquaculture Ponds | Aquaculture233(1-4): 197-203 | 2004 | 2018/03/06 | ||||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LOEC | 18 | days | 0.1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 0.67 | hours | 0.05 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2017/03/15 | ||||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | IC50 | 4 | hours | 2.6 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2017/03/15 | ||||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | LOEC | 4 | hours | 1.2 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Physiology | EC50 | 2 | hours | 39 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Vedrine,C., J.C. Leclerc, C. Durrieu, and C. Tran-Minh | Optical Whole-Cell Biosensor Using Chlorella vulgaris Designed for Monitoring Herbicides | Biosens. Bioelectron.18(4): 457-463 | 2003 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Population | EC10 | 1 | hours | 1.3 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 0.33 | hours | 13.8 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 0.33 | hours | 0.5 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Navicula sp. Navicula sp. | Physiology | IC10 | 4 | hours | 0.78 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | NOEC | 0.33 | hours | 0.1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Chlorella sp. Chlorella sp. | Mortality | 47000~120000 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Kvitko,K.V., B.T. Mukhamadiev, and O.V. Zalenskii | Effect of DCMU, an Inhibitor of Photophosphorylation, on the Variability of Chlorella | In: Y.S.Nasyrov (Ed.), Genet.Aspektyfotosin., Dushanbe, USSR:255-268 | 1971 | 2017/03/23 | ||||||||||
| 藻類 | Chlorella vulgaris | Population | LOEC | 0.33 | hours | 0.5 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 0.67 | hours | 0.07 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Population | NOEC | 0.33 | hours | 0.1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Biochemical | EC50 | 0.08 | hours | 0.01 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Naessens,M., J.C. Leclerc, and C. Tran-Minh | Fiber Optic Biosensor Using Chlorella vulgaris for Determination of Toxic Compounds | Ecotoxicol. Environ. Saf.46(2): 181-185 | 2000 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 1 | hours | 20 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Physiology | LOEC | 1.33 | hours | <43 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8): 2615-2626 | 2012 | 2017/03/15 | ||||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 0.33 | hours | 27.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2017/03/15 | ||||||
| 藻類 | Navicula pelliculosa | Physiology | LOEC | 1.33 | hours | <43 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8): 2615-2626 | 2012 | 2017/03/15 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Physiology | 1.33 | hours | <=250 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8): 2615-2626 | 2012 | 2016/03/25 | |||||||
| 藻類 | Pseudokirchneriella subcapitata | Population | 0.1~10 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, C.S. Tucker, and S.O. Duke | A Rapid Bioassay for Selective Algicides | Weed Technol.11(4): 767-774 | 1997 | 2016/03/25 | ||||||||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 4 | days | 6.9 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3): 184-191 | 2007 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Mortality | 10 | hours | 4 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ukeles,R. | Growth of Pure Cultures of Marine Phytoplankton in the Presence of Toxicants | Appl. Microbiol.10:532-537 | 1962 | 2018/03/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population | EC10 | 1 | hours | 0.84 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC50 | 3 | days | 24 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Physiological | EC50 | 1.5 | hours | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10:45-48 | 1972 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 1 | hours | 28 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12): 1757-1762 | 1983 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Biochemical | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Biochemical | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC50 | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Enzyme | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Enzyme | EC50 | 2 | hours | >200000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Peterson,S.M., and J.L. Stauber | New Algal Enzyme Bioassay for the Rapid Assessment of Aquatic Toxicity | Bull. Environ. Contam. Toxicol.56(5): 750-757 | 1996 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella sp. | Mortality | 10 | days | 400 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ukeles,R. | Growth of Pure Cultures of Marine Phytoplankton in the Presence of Toxicants | Appl. Microbiol.10:532-537 | 1962 | 2018/03/16 | ||||||
| 藻類 | Skeletonema costatum | Population | EC10 | 4 | days | 3.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5): 1147-1151 | 2011 | 2018/03/16 | |||||
| 藻類 | Skeletonema costatum | Population | EC50 | 4 | days | 5.9 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5): 1147-1151 | 2011 | 2018/03/16 | |||||
| 藻類 | Skeletonema costatum | Population | EC50 | 2 | days | 13000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macedo,R.S., A.T. Lombardi, C.Y. Omachi, and L.R. Rorig | Effects of the Herbicide Bentazon on Growth and Photosystem II Maximum Quantum Yield of the Marine Diatom Skeletonema costatum | Toxicol. In Vitro22(3): 716-722 | 2008 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 3 | days | 45 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mezcua,M., M.D. Hernando, L. Piedra, A. Aguera, and A.R. Fernandez-Alba | Chromatography-Mass Spectrometry and Toxicity Evaluation of Selected Contaminants in Seawater | Chromatographia (Wiesb.)56(3/4): 199-206 | 2002 | 2018/03/16 | |||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 3 | days | 45 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Shi,Y., M. Burns, R.J. Ritchie, A. Crossan, and I.R. Kennedy | Probabilistic Risk Assessment of Diuron and Prometryn in the Gwydir River Catchment, Australia, with the Input of a Novel Bioassay Based on Algal Growth | Ecotoxicol. Environ. Saf.106:213-219 | 2014 | 2018/03/16 | |||||
| 藻類 | Chlorella vulgaris | Population | IC10 | 0.15 | hours | 0.1 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC10 | 0.5 | hours | 0.19 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Skeletonema costatum | Physiological | IC50 | 0.25 | hours | 0.7 | μM | TOTAL | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4): 335-342 | 1976 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 3 | days | 15 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mezcua,M., M.D. Hernando, L. Piedra, A. Aguera, and A.R. Fernandez-Alba | Chromatography-Mass Spectrometry and Toxicity Evaluation of Selected Contaminants in Seawater | Chromatographia (Wiesb.)56(3/4): 199-206 | 2002 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Population | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Scenedesmus subspicatus | Population | IC10 | 1.2 | hours | 0.19 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 1 | hours | 18 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12): 1757-1762 | 1983 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Population | EC50 | 1 | hours | 18 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2018/03/16 | |||||
| 藻類 | Chlorella sp. Chlorella sp. | Physiological | EC50 | 1.5 | hours | 19 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5): 291-295 | 1973 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Population | EC50 | 4.5 | hours | 1.8 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Sjollema,S.B., G. MartinezGarcia, H.G. Van der Geest, M.H.S. Kraak, P. Booij, A.D. Vethaak, and W. Admiraal | Hazard and Risk of Herbicides for Marine Microalgae | Environ. Pollut.187:106-111 | 2014 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | EC50 | 1.5 | hours | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10:45-48 | 1972 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | EC50 | 1.5 | hours | 50 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5): 291-295 | 1973 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 4.5 | hours | 2.9 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Booij,P., S.B. Sjollema, P.E.G. Leonards, P. De Voogt, G.J. Stroomberg, A.D. Vethaak, and M.H. Lamoree | Extraction Tools for Identification of Chemical Contaminants in Estuarine and Coastal Waters to Determine Toxic Pressure on Primary Producers | Chemosphere93:107-114 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Physiological | EC50 | 1.5 | hours | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5): 291-295 | 1973 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | IC10 | 0.75 | hours | 0.11 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 4 | days | 9.2 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | IC10 | 4 | days | 0.42 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | EC50 | 1.5 | hours | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5): 291-295 | 1973 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Population | IC10 | 0.12 | hours | 0.11 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Population | IC50 | 3 | days | 0.09 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Clarkson,N., J.W. Leftley, D.T. Meldrum, and J.W. Watson | An Assessment of the Cage-Culture Turbidostat as an Alternative Algal Bioassay | Water Res.32(4): 1162-1168 | 1998 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC10 | 3 | days | 10 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC10 | 3 | days | 2.5 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula cryptotenella | Population | EC10 | 2 | days | >500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Wood,R.J., S.M. Mitrovic, R.P. Lim, and B.J. Kefford | How Benthic Diatoms Within Natural Communities Respond to Eight Common Herbicides with Different Modes of Action | Sci. Total Environ.557-558:636-643 | 2016 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC50 | 3 | days | 33 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Physiological | EC50 | 0.25 | hours | 1 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Samson,G., and R. Popovic | Use of Algal Fluorescence for Determination of Phytotoxicity of Heavy Metals and Pesticides as Environmental Pollutants | Ecotoxicol. Environ. Saf.16(3): 272-278 | 1988 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus quadricauda | Population | IC10 | 0.67 | hours | 0.19 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4): 315-326 | 2005 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 1 | days | 35 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12): 1757-1762 | 1983 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | EC50 | 4 | days | 4.9 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3): 184-191 | 2007 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula incerta | Physiological | EC50 | 1.5 | hours | 93 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5): 291-295 | 1973 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Population | EC10 | 3 | days | 4.3 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula cryptotenella | Population | EC50 | 2 | days | >500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Wood,R.J., S.M. Mitrovic, R.P. Lim, and B.J. Kefford | How Benthic Diatoms Within Natural Communities Respond to Eight Common Herbicides with Different Modes of Action | Sci. Total Environ.557-558:636-643 | 2016 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | IC50 | 0.25 | hours | 0.1 | μM | TOTAL | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4): 335-342 | 1976 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Population | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Population | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | IC50 | 4 | hours | 2.71 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | NOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | NOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Population | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | NOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | LOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Population | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Physiological | IC50 | 0.25 | hours | 0.1 | μM | TOTAL | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4): 335-342 | 1976 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Population | IC50 | 7 | hours | 0.33 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Clarkson,N., J.W. Leftley, D.T. Meldrum, and J.W. Watson | An Assessment of the Cage-Culture Turbidostat as an Alternative Algal Bioassay | Water Res.32(4): 1162-1168 | 1998 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | LOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | NOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Phaeodactylum tricornutum | Physiological | LOEC | 4 | hours | 0.1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11): 1978-1987 | 2010 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Population | LOEC | 4 | days | 3.84 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Dunaliella tertiolecta | Biochemical | LOEC | 4 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7): 359-371 | 2013 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Genetic | NOEL | 2 | hours | 10 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Chen,L., M. Xie, Y. Bi, G. Wang, S. Deng, and Y. Liu | The Combined Effects of UV-B Radiation and Herbicides on Photosynthesis, Antioxidant Enzymes and DNA Damage in Two Bloom-Forming Cyanobacteria | Ecotoxicol. Environ. Saf.80:224-230 | 2012 | 2018/03/16 | |||||
| 藻類 | Navicula sp. Navicula sp. | Biochemical | NOEC | 3 | days | 16 | nM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Magnusson,M., K. Heimann, and A.P. Negri | Comparative Effects of Herbicides on Photosynthesis and Growth of Tropical Estuarine Microalgae | Mar. Pollut. Bull.56(9): 1545-1552 | 2008 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 4 | days | 36.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | IC50 | 0.67 | hours | 0.05 | μM | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2): 273-286 | 1997 | 2018/03/16 | |||||
| 藻類 | Scenedesmus subspicatus | Population | EC50 | 3 | days | 36 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1): 64-81 | 1994 | 2018/03/07 | |||||
| 藻類 | Chlorella vulgaris | Physiology | EC50 | 2 | hours | 39 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Vedrine,C., J.C. Leclerc, C. Durrieu, and C. Tran-Minh | Optical Whole-Cell Biosensor Using Chlorella vulgaris Designed for Monitoring Herbicides | Biosens. Bioelectron.18(4): 457-463 | 2003 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Population | NOEC | 0.33 | hours | 0.1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/15 | |||||
| 藻類 | Desmodesmus subspicatus | Population | EC50 | 3 | days | 46.3 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1): 117-122 | 2011 | 2018/03/15 | |||||
| 藻類 | Chlorella vulgaris | Population | EC10 | 1 | hours | 1.3 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 3 | days | 19.5 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2): 377-386 | 2012 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC100 | 5 | days | 1 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2): 85-99 | 1998 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEC | 0.33 | hours | 0.5 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3): 261-271 | 2005 | 2018/03/16 | |||||
| 藻類 | Navicula pelliculosa | Physiology | LOEC | 1.3 | hours | <43 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8): 2615-2626 | 2012 | 2018/03/15 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Physiology | LOEC | 1.3 | hours | <43 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8): 2615-2626 | 2012 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | LOEL | 4 | days | 10 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/16 | |||||
| 藻類 | Pseudokirchneriella subcapitata | Population | EC50 | 4 | days | 2.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/16 | |||||
| 藻類 | Chlorella vulgaris | Population | EC50 | 1 | hours | 20 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Muller,R., U. Schreiber, B.I. Escher, P. Quayle, S.M.B. Nash, and J.F. Mueller | Rapid Exposure Assessment of PSII Herbicides in Surface Water Using a Novel Chlorophyll a Fluorescence Imaging Assay | Sci. Total Environ.401(1-3): 51-59 | 2008 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | EC50 | 3 | days | 23 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Liu,W., Y.B. Zhang, X. Quan, Y.H. Jin, and S. Chen | Effect of Perfluorooctane Sulfonate on Toxicity and Cell Uptake of Other Compounds with Different Hydrophobicity in Green Alga | Chemosphere75(3): 405-409 | 2009 | 2018/03/16 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | LOEC | 1 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3): 178-185 | 2002 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena variabilis | Population | LC50 | 14 | days | 5.8 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | EC50 | 4 | days | 2.3 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Ma,J., L. Xu, and S. Wang | A Quick, Simple, and Accurate Method of Screening Herbicide Activity Using Green Algae Cell Suspension Cultures | Weed Sci.50(5): 555-559 | 2002 | 2018/03/07 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Physiology | EC10 | 1 | days | 0.77819 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139:65-72 | 2015 | 2018/03/06 | |||||
| 藻類 | Anabaena sp. Anabaena sp. | Physiology | LOEC | 1 | days | >0~<10 | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139:65-72 | 2015 | 2018/03/15 | ||||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Physiology | NOEC | 0.67 | hours | 5 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6): 587-593 | 1976 | 2018/03/15 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus acutus var. acutus | Population | IC50 | 1 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geoffroy,L., M. Couderchet, and G. Vernet | Catalase Activity of Scenedesmus obliquus as a Biomarker of Environmental Pollution by Herbicides and Copper | Meded. Fac. Landbouwwet. Rijksuniv. Gent65(2B): 843-852 | 2000 | 2018/03/16 | |||||
| 藻類 | Anabaena sp. Anabaena doliolum | Population | IC50 | 12 | days | 1000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Singh,D.P., and K. Kshatriya | Characterization of Salinity-Tolerant Mutant of Anabaena doliolum Exhibiting Multiple Stress Tolerance | Curr. Microbiol.45(3): 165-170 | 2002 | 2018/03/06 | |||||
| 藻類 | Navicula sp. Navicula forcipata | Population | EC50 | 4 | days | 25 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3): 184-191 | 2007 | 2018/03/15 | |||||
| 藻類 | Chlorella sp. Chlorella pyrenoidosa | Population | LC50 | 14 | days | 30 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2018/03/07 | |||||
| 藻類 | Scenedesmus sp. Scenedesmus quadricauda | Population | LC50 | 14 | days | 50 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2): 155-172 | 1981 | 2018/03/07 | |||||
| 藻類 | Anabaena flos-aquae | growth rate | EC50 | 72 | hours | 30.9 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1998 | 2017/01/27 | ||||||
| 藻類 | Anabaena flos-aquae | biomass | EC50 | 72 | hours | 232 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1998 | 2017/01/27 | ||||||
| 藻類 | Desmodesmus subspicatus | growth rate | EC50 | 96 | hours | 22 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1991 | 2018/02/07 | ||||||
| 藻類 | Scenedesmus subspicatus | EC50 | 96 | hours | 7 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F. Jewett | 2015 | 2018/02/21 | |||||||||
| 藻類 | Desmodesmus subspicatus | biomass | EC50 | 96 | hours | 7.9 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1991 | 2018/02/07 | ||||||
| 藻類 | Anabaena flos-aquae | growth rate | EC50 | 72 | hours | 30.9 | μg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | EC50 | 96 | hours | 6.9 | μg/L | × | 16 ECOTOX | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3) | 2020/11/16 | ||||||
| 藻類 | Anabaena flos-aquae | biomass | EC50 | 72 | hours | 232 | μg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 藻類 | Desmodesmus subspicatus | Population/Photosynthesis | EC50 | 49~<=79 | minutes | 0.073 | mg/L | × | 16 ECOTOX | Nendza,M., and A. Wenzel | Discriminating Toxicant Classes by Mode of Action 1. (Eco)toxicity Profiles | Environ. Sci. Pollut. Res.13(3) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | growth rate | EC50 | 72 | hours | 22 | μg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Desmodesmus subspicatus | growth rate | EC50 | 96 | hours | 22 | μg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Desmodesmus subspicatus | biomass | EC50 | 72 | hours | 9 | μg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Anabaena flos-aquae | biomass | EC50 | 72 | hours | 232 | μg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Anabaena flos-aquae | growth rate | EC50 | 72 | hours | 30.9 | μg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Skeletonema costatum | Physiology/Photosynthesis | IC50 | 15 | minutes | 0.0000007 | M | × | 16 ECOTOX | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Physiology/Photosynthesis | EC50 | 90 | minutes | 0.01 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | IC50 | 24 | hours | 10 | μg/L | × | 16 ECOTOX | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Photosynthesis | IC50 | 40 | minutes | 0.05 | μM | × | 16 ECOTOX | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | EC50 | 3 | days | 0.1 | mg/L | × | 16 ECOTOX | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11) | 2020/11/16 | ||||||
| 藻類 | Skeletonema costatum | Population/Photosynthesis | EC50 | 48 | hours | 13 | mg/L | × | 16 ECOTOX | Macedo,R.S., A.T. Lombardi, C.Y. Omachi, and L.R. Rorig | Effects of the Herbicide Bentazon on Growth and Photosystem II Maximum Quantum Yield of the Marine Diatom Skeletonema costatum | Toxicol. In Vitro22(3) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | EC50 | 72 | hours | 0.023 | mg/L | × | 16 ECOTOX | Liu,W., Y.B. Zhang, X. Quan, Y.H. Jin, and S. Chen | Effect of Perfluorooctane Sulfonate on Toxicity and Cell Uptake of Other Compounds with Different Hydrophobicity in Green Alga | Chemosphere75(3) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | EC50 | 96 | hours | 4.9 | μg/L | × | 16 ECOTOX | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | ErC50 | 72 | hours | 28.8 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 藻類 | Pseudokirchneriella subcapitata | ErC50 | 72 | hours | 25 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 藻類 | Chlorella sp. | EC50 | 72 | hours | 19 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F.L. Mayer | 1986 | 2018/02/21 | |||||||||
| 藻類 | Navicula sp. Navicula incerta | EC50 | 72 | hours | 93 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F.L. Mayer | 1986 | 2018/02/21 | |||||||||
| 藻類 | Desmodesmus subspicatus | growth rate | EC50 | 72 | hours | 22 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1991 | 2018/02/07 | ||||||
| 藻類 | Desmodesmus subspicatus | biomass | EC50 | 72 | hours | 9 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1991 | 2018/02/07 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | EC50 | 96 | hours | 2.4 | ppb | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1994 | 2018/02/21 | |||||||||
| 藻類 | Anabaena variabilis | Population/Population growth rate | IC50 | 14 | days | 5.8 | μg/dm3 | × | 16 ECOTOX | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | EC50 | 72 | hours | 22.3 | μg/L | × | 16 ECOTOX | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population/Population growth rate | IC50 | 72 | hours | 0.09 | μM | × | 16 ECOTOX | Clarkson,N., J.W. Leftley, D.T. Meldrum, and J.W. Watson | An Assessment of the Cage-Culture Turbidostat as an Alternative Algal Bioassay | Water Res.32(4) | 2020/11/16 | ||||||
| 藻類 | Anabaena variabilis | Population/Population growth rate | IC50 | 10 | days | 0.03 | mg/L | × | 16 ECOTOX | Singh,S., P. Datta, and A. Tirkey | Response of Multiple Herbicide Resistant Strain of Diazotrophic Cyanobacterium, Anabaena variabilis, Exposed to Atrazine and DCMU | Indian J. Exp. Biol.49(4) | 2020/11/16 | ||||||
| 藻類 | Anabaena doliolum | Population/Population growth rate | IC50 | 12 | days | 1 | μg/mL | × | 16 ECOTOX | Singh,D.P., and K. Kshatriya | Characterization of Salinity-Tolerant Mutant of Anabaena doliolum Exhibiting Multiple Stress Tolerance | Curr. Microbiol.45(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Biomass | EC50 | 96 | hours | 0.02 | μmol/dm3 | × | 16 ECOTOX | Shitanda,I., K. Takada, Y. Sakai, and T. Tatsuma | Compact Amperometric Algal Biosensors for the Evaluation of Water Toxicity | Anal. Chim. Acta530(2) | 2020/11/16 | ||||||
| 藻類 | Anabaena variabilis | Population/Population growth rate | IC50 | 10 | days | 0.08 | mg/L | × | 16 ECOTOX | Singh,S., P. Datta, and A. Tirkey | Response of Multiple Herbicide Resistant Strain of Diazotrophic Cyanobacterium, Anabaena variabilis, Exposed to Atrazine and DCMU | Indian J. Exp. Biol.49(4) | 2020/11/16 | ||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | EC50 | 24 | hours | 0.00378092 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Photosynthesis | EC50 | 1 | hours | 0.018 | mg/L | × | 16 ECOTOX | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | EC50 | 96 | hours | 9.2 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Navicula forcipata | Population/Population growth rate | EC50 | 96 | hours | 25 | μg/L | × | 16 ECOTOX | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Chlorophyll | IC50 | 24 | hours | 0.01 | mg/L | × | 16 ECOTOX | Geoffroy,L., M. Couderchet, and G. Vernet | Catalase Activity of Scenedesmus obliquus as a Biomarker of Environmental Pollution by Herbicides and Copper | Meded. Fac. Landbouwwet. Rijksuniv. Gent65(2B) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Photosynthesis | EC50 | 20 | minutes | 27.4 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Physiology/Photosynthesis | EC50 | 90 | minutes | 0.01 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Physiology/Photosynthesis | IC50 | 15 | minutes | 0.0000001 | M | × | 16 ECOTOX | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus | Population/Abundance | IC50 | 24 | hours | 0.000000057 | M | × | 16 ECOTOX | Grossmann,K., R. Berghaus, and G. Retzlaff | Heterotrophic Plant Cell Suspension Cultures for Monitoring Biological Activity in Agrochemical Research. Comparison with Screens Using Algae, Germinating Seeds and Whole Plants | Pestic. Sci.35(3) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | IC50 | 72 | hours | 0.03 | μM | × | 16 ECOTOX | Fai,P.B., A. Grant, and B.J. Reid | Compatibility of Hydroxypropyl-beta-Cyclodextrin with Algal Toxicity Bioassays | Environ. Pollut.157(1) | 2020/11/16 | ||||||
| 藻類 | Thalassiosira pseudonana | Physiology/Photosynthesis | EC50 | 1.5 | hours | 39 | μg/L | × | 16 ECOTOX | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | IC50 | 72 | hours | 10.5 | μg/L | × | 16 ECOTOX | Fai,P.B., A. Grant, and B. Reid | Chlorophyll a Fluorescence as a Biomarker for Rapid Toxicity Assessment | Environ. Toxicol. Chem.26(7) | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 24 | hours | 0.03 | μM | × | 16 ECOTOX | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population/Population growth rate | EC50 | 10 | days | 0.01 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Photosynthesis | EC50 | 1 | hours | 0.028 | mg/L | × | 16 ECOTOX | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population/Population growth rate | IC50 | 7 | days | 0.33 | μM | × | 16 ECOTOX | Clarkson,N., J.W. Leftley, D.T. Meldrum, and J.W. Watson | An Assessment of the Cage-Culture Turbidostat as an Alternative Algal Bioassay | Water Res.32(4) | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 24 | hours | 0.05 | μM | × | 16 ECOTOX | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus quadricauda | Population/Population growth rate | EC50 | 96 | hours | 0.0027 | mg/L | × | 16 ECOTOX | Ma,J., F. Lin, S. Wang, and L. Xu | Toxicity of 21 Herbicides to the Green Alga Scenedesmus quadricauda | Bull. Environ. Contam. Toxicol.71(3) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | EC50 | 72 | hours | 24 | μg/L | × | 16 ECOTOX | Katsumata,M., T. Koike, K. Kazumura, A. Takeuchi, and Y. Sugaya | Utility of Delayed Fluorescence as Endpoint for Rapid Estimation of Effect Concentration on the Green Alga Pseudokirchneriella subcapitata | Bull. Environ. Contam. Toxicol.83(4) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Population growth rate | EC50 | 72 | hours | 36 | μg/L | × | 16 ECOTOX | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1) | 2020/11/16 | ||||||
| 藻類 | Skeletonema costatum | Population/Population growth rate | EC50 | 96 | hours | 5.9 | μg/L | × | 16 ECOTOX | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5) | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 24 | hours | 0.04 | μM | × | 16 ECOTOX | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1) | 2020/11/16 | ||||||
| 藻類 | Thalassiosira pseudonana | Population/Population growth rate | EC50 | 96 | hours | 4.3 | μg/L | × | 16 ECOTOX | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Population growth rate | EC50 | 72 | hours | 45 | μg/L | × | 16 ECOTOX | Shi,Y., M. Burns, R.J. Ritchie, A. Crossan, and I.R. Kennedy | Probabilistic Risk Assessment of Diuron and Prometryn in the Gwydir River Catchment, Australia, with the Input of a Novel Bioassay Based on Algal Growth | Ecotoxicol. Environ. Saf.106 | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Photosynthesis | EC50 | 24 | hours | 0.035 | mg/L | × | 16 ECOTOX | McFeters,G.A., P.J. Bond, S.B. Olson, and Y.T. Tchan | A Comparison of Microbial Bioassays for the Detection of Aquatic Toxicants | Water Res.17(12) | 2020/11/16 | ||||||
| 藻類 | Navicula lanceolata | Population/Population growth rate | EC50 | 4~6 | days | >5~10 | μg/L | × | 16 ECOTOX | Roubeix,V., S. Pesce, N. Mazzella, M. Coste, and F. Delmas | Variations in Periphytic Diatom Tolerance to Agricultural Pesticides in a Contaminated River: An Analysis from Community to Population Level | In: Proceedings of the International Conference on Environmental Management, Engineering, Planning and Economics and SECOTOX Conference | 2020/11/16 | ||||||
| 藻類 | Anabaena inaequalis | Population/Photosynthesis | EC50 | 2 | hours | 0.04 | ppm | × | 16 ECOTOX | Stratton,G.W., A.L. Huber, and C.T. Corke | The Effect of Pesticides and Their Metabolites, Alone and in Combination, on Algal Processes | Can. Tech. Rep. Fish. Aquat. Sci.975 | 2020/11/16 | ||||||
| 藻類 | Thalassiosira pseudonana | Population/Photosystem II (PSII) electron transport activity | EC50 | 4.5 | hours | 2.9 | μg/L | × | 16 ECOTOX | Sjollema,S.B., G. MartinezGarcia, H.G. Van der Geest, M.H.S. Kraak, P. Booij, A.D. Vethaak, and W. Admiraal | Hazard and Risk of Herbicides for Marine Microalgae | Environ. Pollut.187 | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | EC50 | 72 | hours | 0.045 | mg/L | × | 16 ECOTOX | Mezcua,M., M.D. Hernando, L. Piedra, A. Aguera, and A.R. Fernandez-Alba | Chromatography-Mass Spectrometry and Toxicity Evaluation of Selected Contaminants in Seawater | Chromatographia (Wiesb.)56(3/4) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | EC50 | 14 | days | 30 | μg/dm3 | × | 16 ECOTOX | Bednarz,T. | The Effect of Pesticides on the Growth of Green and Blue-Green Algae Cultures | Acta Hydrobiol.23(2) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Population growth rate | EC50 | 72 | hours | 46.3 | μg/L | × | 16 ECOTOX | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1) | 2020/11/16 | ||||||
| 藻類 | Navicula forcipata | Population/Population growth rate | EC50 | 96 | hours | 28 | μg/L | × | 16 ECOTOX | Gatidou,G., and N.S. Thomaidis | Evaluation of Single and Joint Toxic Effects of Two Antifouling Biocides, Their Main Metabolites and Copper Using Phytoplankton Bioassays | Aquat. Toxicol.85(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 48 | hours | 14.3 | μg/L | 16 ECOTOX | Copin,P.J., and N. Chevre | Modelling the Effects of Pulse Exposure of Several PSII Inhibitors on Two Algae | Chemosphere137 | 2020/11/16 | |||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | IC50 | 96 | hours | 36.4 | μg/L | × | 16 ECOTOX | Schrader,K.K., M.Q. De Regt, P.D. Tidwell, C.S. Tucker, and S.O. Duke | Compounds with Selective Toxicity Towards the Off-Flavor Metabolite-Producing Cyanobacterium Oscillatoria cf. chalybea | Aquaculture163(1-2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | EC50 | 96 | hours | 0.0007 | mg/L | × | 16 ECOTOX | Ma,J., S. Wang, P. Wang, L. Ma, X. Chen, and R. Xu | Toxicity Assessment of 40 Herbicides to the Green Alga Raphidocelis subcapitata | Ecotoxicol. Environ. Saf.63(3) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Physiology/Photosynthesis | EC50* | 0.25 | hours | 1 | μM | × | 16 ECOTOX | Samson,G., and R. Popovic | Use of Algal Fluorescence for Determination of Phytotoxicity of Heavy Metals and Pesticides as Environmental Pollutants | Ecotoxicol. Environ. Saf.16(3) | 2020/11/16 | ||||||
| 藻類 | Navicula incerta | Physiology/Photosynthesis | EC50 | 1.5 | hours | 93 | μg/L | × | 16 ECOTOX | Hollister,T.A., and G.E. Walsh | Differential Responses of Marine Phytoplankton to Herbicides: Oxygen Evolution | Bull. Environ. Contam. Toxicol.9(5) | 2020/11/16 | ||||||
| 藻類 | Anabaena doliolum | Population/Population growth rate | IC50 | 12 | days | 0.4 | μg/mL | × | 16 ECOTOX | Singh,D.P., and K. Kshatriya | Characterization of Salinity-Tolerant Mutant of Anabaena doliolum Exhibiting Multiple Stress Tolerance | Curr. Microbiol.45(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | EC50 | 96 | hours | 0.0023 | mg/L | × | 16 ECOTOX | Ma,J., L. Xu, and S. Wang | A Quick, Simple, and Accurate Method of Screening Herbicide Activity Using Green Algae Cell Suspension Cultures | Weed Sci.50(5) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Physiology/Photosynthesis | IC50 | 15 | minutes | 0.0000001 | M | × | 16 ECOTOX | Overnell,J. | Inhibition of Marine Algal Photosynthesis by Heavy Metals | Mar. Biol.38(4) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Photosynthesis | IC50 | 40 | minutes | 0.07 | μM | × | 16 ECOTOX | El Jay,A., J.M. Ducruet, J.C. Duval, and J.P. Pelletier | A High-Sensitivity Chlorophyll Fluorescence Assay for Monitoring Herbicide Inhibition of Photosystem II in the Chlorophyte Selenastrum capricornutum: Comparison with Effect on Cell Growth | Arch. Hydrobiol.140(2) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Population growth rate | EC50 | 72 | hours | 54 | μg/L | × | 16 ECOTOX | Masojidek,J., P. Soucek, J. Machova, J. Frolik, K. Klem, and J. Maly | Detection of Photosynthetic Herbicides: Algal Growth Inhibition Test vs. Electrochemical Photosystem II Biosensor | Ecotoxicol. Environ. Saf.74(1) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | EC50 | 96 | hours | 0.0013 | mg/L | × | 16 ECOTOX | Ma,J., W. Liang, L. Xu, S. Wang, Y. Wei, and J. Lu | Acute Toxicity of 33 Herbicides to the Green Alga Chlorella pyrenoidosa | Bull. Environ. Contam. Toxicol.66(4) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Photosynthesis | EC50 | 20 | minutes | 13.8 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Navicula cryptotenella | Population/Abundance | EC50 | 48 | hours | 500 | μg/L | 16 ECOTOX | Wood,R.J., S.M. Mitrovic, R.P. Lim, and B.J. Kefford | How Benthic Diatoms Within Natural Communities Respond to Eight Common Herbicides with Different Modes of Action | Sci. Total Environ.557-558 | 2020/11/16 | |||||||
| 藻類 | Chlorella vulgaris | Population/Population growth rate | EC50 | 96 | hours | 0.0043 | mg/L | × | 16 ECOTOX | Ma,J., L. Xu, S. Wang, R. Zheng, S. Jin, S. Huang, and Y. Huang | Toxicity of 40 Herbicides to the Green Alga Chlorella vulgaris | Ecotoxicol. Environ. Saf.51(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | EC50 | 72 | hours | 0.045 | mg/L | × | 16 ECOTOX | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | EC50 | 72 | hours | 0.045 | mg/L | × | 16 ECOTOX | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2 | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 24 | hours | 0.04 | μM | × | 16 ECOTOX | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | EC50 | 10 | days | 0.02 | ppm | × | 16 ECOTOX | Walsh,G.E. | Effects of Herbicides on Photosynthesis and Growth of Marine Unicellular Algae | Hyacinth Control J.10 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | EC50 | 96 | hours | 0.00409 | mg/L | × | 16 ECOTOX | Ma,J. | Differential Sensitivity to 30 Herbicides Among Populations of Two Green Algae Scenedesmus obliquus and Chlorella pyrenoidosa | Bull. Environ. Contam. Toxicol.68(2) | 2020/11/16 | ||||||
| 藻類 | Chlorella fusca var. vacuolata | Population/Population growth rate | EC50 | 24 | hours | 0.03 | μM | × | 16 ECOTOX | Neuwoehner,J., and B.I. Escher | The pH-Dependent Toxicity of Basic Pharmaceuticals in the Green Algae Scenedesmus vacuolatus can be Explained with a Toxicokinetic Ion-Trapping Model | Aquat. Toxicol.101(1) | 2020/11/16 | ||||||
| 藻類 | Anabaena flosaquae | Biomass | EC50 | 72 | hours | 0.023 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 藻類 | Synecoccus leopoliensis | EC50 | 72 | hours | 16.9 | ppb | 3 USEPA Pesticide Ecotoxicity Database | Supplemental | 2021/02/17 | ||||||||||
| 藻類 | Desmodesmus subspicatus | biomass | EC50 | 96 | hours | 7.9 | μg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Phaeodactylum tricornutum | EC50 | 10 | days | 10 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F.L. Mayer | 1985 | 2018/02/21 | |||||||||
| 藻類 | Navicula pelliculosa | EC50 | 72 | hours | 11.1 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F. Jewett | 2015 | 2018/02/21 | |||||||||
| 藻類 | Dunaliella tertiolecta | EC50 | 10 | days | 20 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F.L. Mayer | 1986 | 2018/02/21 | |||||||||
| 藻類 | Anabaena flos-aquae | growth rate | NOEC | 72 | hours | 10 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1998 | 2017/01/27 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | NOEL | 96 | hours | 0.44 | ppb | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1994 | 2018/02/21 | |||||||||
| 藻類 | Scenedesmus subspicatus | NOEL | 96 | hours | 2.3 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F. Jewett | 2015 | 2018/02/21 | |||||||||
| 藻類 | Pseudokirchneriella subcapitata | NOErC | 72 | hours | 4.4 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 ジウロン(DCMU) | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 藻類 | Navicula pelliculosa | NOEL | 72 | hours | 9.17 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F. Jewett | 2015 | 2018/02/21 | |||||||||
| 藻類 | Anabaena flos-aquae | growth rate | EC10 | 72 | hours | 10.1 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1998 | 2017/01/27 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | NOErC | 72 | hours | 3.6 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 ジウロン(DCMU) | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 藻類 | Anabaena flos-aquae | growth rate | NOEC | 72 | hours | 10 | μg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 藻類 | Scenedesmus quadricauda | Population/Chlorophyll | IC10 | 40 | minutes | 0.19 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | growth rate | NOEC | 96 | hours | 3.2 | μg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Anabaena flos-aquae | growth rate | NOEC | 72 | hours | 10 | μg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Anabaena flos-aquae | growth rate | EC10 | 72 | hours | 10.1 | μg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | LOEC | 120 | minutes | 0.00000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | LOEC | 40 | minutes | 0.000000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Population growth rate | NOEC | 72 | hours | 10 | μg/L | × | 16 ECOTOX | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 9 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Respiration | LOEC | 100 | minutes | 0.0000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 12 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 12 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | NOEC | 15 | minutes | 0.02 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Scenedesmus opoliensis | Physiology/Photosynthesis | LOEC | 10 | days | 10 | μM | × | 16 ECOTOX | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Respiration | NOEC | 120 | minutes | 0.00000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Respiration | LOEC | 120 | minutes | 0.0000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | growth rate | NOEC | 96 | hours | 3.2 | μg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1991 | 2018/02/07 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Population growth rate | NOEC | 24 | hours | 7 | μg/L | × | 16 ECOTOX | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Physiology/Photosynthesis | IC10 | 4 | hours | 0.42 | μg/L | × | 16 ECOTOX | Magnusson,M., K. Heimann, P. Quayle, and A.P. Negri | Additive Toxicity of Herbicide Mixtures and Comparative Sensitivity of Tropical Benthic Microalgae | Mar. Pollut. Bull.60(11) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 21 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | LOEC | 15 | minutes | 0.04 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | LOEC | 24 | hours | >0~0.01 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 15 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Thalassiosira pseudonana | Population/Population growth rate | EC10 | 96 | hours | 1.592 | μg/L | × | 16 ECOTOX | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Chlorophyll | IC10 | 9 | minutes | 0.1 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Photosynthesis | LOEC | 20 | minutes | 0.5 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 6 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Navicula cryptotenella | Population/Abundance | EC10 | 48 | hours | 500 | μg/L | 16 ECOTOX | Wood,R.J., S.M. Mitrovic, R.P. Lim, and B.J. Kefford | How Benthic Diatoms Within Natural Communities Respond to Eight Common Herbicides with Different Modes of Action | Sci. Total Environ.557-558 | 2020/11/16 | |||||||
| 藻類 | Anabaena sp. | Physiology/Bioluminescence | EC10 | 24 | hours | 0.00077819 | mg/L | × | 16 ECOTOX | Rodea-Palomares,I., M. Makowski, S. Gonzalo, M. Gonzalez-Pleiter, F. Leganes, and F. Fernandez-Pinas | Effect of PFOA/PFOS Pre-Exposure on the Toxicity of the Herbicides 2,4-D, Atrazine, Diuron and Paraquat to a Model Aquatic Photosynthetic Microorganism | Chemosphere139 | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Abundance | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 6 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 9 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Phaeodactylum tricornutum | Population/Chlorophyll | IC10 | 7 | minutes | 0.11 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Abundance | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 3 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Chlorophyll | IC10 | 30 | minutes | 0.19 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Chlorophyll | IC10 | 24 | hours | 0.004 | mg/L | × | 16 ECOTOX | Geoffroy,L., M. Couderchet, and G. Vernet | Catalase Activity of Scenedesmus obliquus as a Biomarker of Environmental Pollution by Herbicides and Copper | Meded. Fac. Landbouwwet. Rijksuniv. Gent65(2B) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | LOEC | 100 | minutes | 0.000000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 18 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus opoliensis | Population/Dry Biomass | LOEC | 10 | days | 10 | μM | × | 16 ECOTOX | Fodorpataki,L., C. Bartha, and Z.G. Keresztes | Stress-Physiological Reactions of the Green Alga Scenedesmus opoliensis to Water Pollution with Herbicides | An. Univ. Oradea Fasc. Biol.16(1) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | LOEC | 60 | minutes | 0.00000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Respiration | NOEC | 100 | minutes | 0.00000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Photosynthesis | LOEC | 20 | minutes | 0.5 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Population/Chlorophyll | IC10 | 70 | minutes | 0.19 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 15 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Population growth rate | LOEC | 96 | hours | 3.84 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Chlorophyll | IC10 | 45 | minutes | 0.11 | μg/L | × | 16 ECOTOX | Bengtson Nash,S.M., P.A. Quayle, U. Schreiber, and J.F. Muller | The Selection of a Model Microalgal Species as Biomaterial for a Novel Aquatic Phytotoxicity Assay | Aquat. Toxicol.72(4) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | NOEC | 60 | minutes | 0.000000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 18 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | IC10 | 24 | hours | 4 | μg/L | × | 16 ECOTOX | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | LOEC | 80 | minutes | 0.000000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Scenedesmus acutus var. acutus | Population/Population growth rate | LOEC | 24 | hours | 10 | μg/L | × | 16 ECOTOX | Geoffroy,L., H. Teisseire, M. Couderchet, and G. Vernet | Effect of Oxyfluorfen and Diuron Alone and in Mixture on Antioxidative Enzymes of Scenedesmus obliquus | Pestic. Biochem. Physiol.72(3) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Respiration | NOEC | 40 | minutes | 0.000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Anabaena flos-aquae | growth rate | EC10 | 72 | hours | 10.1 | μg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 藻類 | Chlorella pyrenoidosa | Physiology/Photosynthesis | NOEC | 120 | minutes | 0.000000005 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | LOEC | 3 | days | 0.0000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Chlorella pyrenoidosa | Population/Population growth rate | NOEC | 21 | days | 0.00000001 | M | × | 16 ECOTOX | Davis,D.E., C.G.P. Pillai, and B. Truelove | Effects of Prometryn, Diuron, Fluometuron, and MSMA on Chlorella and Two Fungi | Weed Sci.24(6) | 2020/11/16 | ||||||
| 藻類 | Skeletonema costatum | Population/Population growth rate | EC10 | 96 | hours | 3.8 | μg/L | × | 16 ECOTOX | Bao,V.W.W., K.M.Y. Leung, J.W. Qiu, and M.H.W. Lam | Acute Toxicities of Five Commonly Used Antifouling Booster Biocides to Selected Subtropical and Cosmopolitan Marine Species | Mar. Pollut. Bull.62(5) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | LOEC | 72 | hours | 0.015 | mg/L | × | 16 ECOTOX | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Abundance | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 藻類 | Navicula pelliculosa | Physiology/Photosystem II (PSII) electron transport activity | LOEC/ | 80 | minutes | 43 | μM | × | 16 ECOTOX | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8) | 2020/11/16 | ||||||
| 藻類 | Chlorella vulgaris | Population/Photosynthesis | NOEC | 20 | minutes | 0.1 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Desmodesmus subspicatus | Physiology/Photosynthesis | NOEC | 24 | hours | 4 | μg/L | × | 16 ECOTOX | Schafer,H., H. Hettler, U. Fritsche, G. Pitzen, G. Roderer, and A. Wenzel | Biotests Using Unicellular Algae and Ciliates for Predicting Long-Term Effects of Toxicants | Ecotoxicol. Environ. Saf.27(1) | 2020/11/16 | ||||||
| 藻類 | Synecoccus leopoliensis | NOEL | 72 | hours | 1.14 | ppb | 3 USEPA Pesticide Ecotoxicity Database | Supplemental | 2021/02/17 | ||||||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | LOEC | 72 | hours | 0.015 | mg/L | × | 16 ECOTOX | Mezcua,M., M.D. Hernando, L. Piedra, A. Aguera, and A.R. Fernandez-Alba | Chromatography-Mass Spectrometry and Toxicity Evaluation of Selected Contaminants in Seawater | Chromatographia (Wiesb.)56(3/4) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Physiology/Photosystem II (PSII) electron transport activity | LOEC/ | 80 | minutes | 43 | μM | × | 16 ECOTOX | Choi,C.J., J.A. Berges, and E.B. Young | Rapid Effects of Diverse Toxic Water Pollutants on Chlorophyll a Fluorescence: Variable Responses Among Freshwater Microalgae | Water Res.46(8) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Abundance | LOEC | 30 | hours | 23 | mg/L | × | 16 ECOTOX | Fernandez-Alba,A.R., M.D. Hernando, L. Piedra, and Y. Chisti | Toxicity Evaluation of Single and Mixed Antifouling Biocides Measured with Acute Toxicity Bioassays | Anal. Chim. Acta456(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Photosynthesis | NOEC | 20 | minutes | 0.1 | μg/L | × | 16 ECOTOX | Podola,B., and M. Melkonian | Selective Real-Time Herbicide Monitoring by an Array Chip Biosensor Employing Diverse Microalgae | J. Appl. Phycol.17(3) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | NOEC | 72 | hours | 9.4 | μg/L | × | 16 ECOTOX | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2) | 2020/11/16 | ||||||
| 藻類 | Pseudokirchneriella subcapitata | Population/Population growth rate | LOEC | 72 | hours | 19.5 | μg/L | × | 16 ECOTOX | Zhang,L.J., G.G. Ying, F. Chen, J.L. Zhao, L. Wang, and Y.X. Fang | Development and Application of Whole-Sediment Toxicity Test Using Immobilized Freshwater Microalgae Pseudokirchneriella subcapitata | Environ. Toxicol. Chem.31(2) | 2020/11/16 | ||||||
| 藻類 | Dunaliella tertiolecta | Population/Abundance | LOEC | 96 | hours | 10 | μg/L | × | 16 ECOTOX | DeLorenzo,M.E., L.E. Danese, and T.D. Baird | Influence of Increasing Temperature and Salinity on Herbicide Toxicity in Estuarine Phytoplankton | Environ. Toxicol.28(7) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Mortality/Mortality | LC10 | 2 | hours | 1000 | μg/L | × | 16 ECOTOX | Tsunemasa,N., and H. Okamura | Effects of Organotin Alternative Antifoulants on Oyster Embryo | Arch. Environ. Contam. Toxicol.61(1) | 2020/11/16 | ||||||
| 甲殻類 | Mercenaria mercenaria | Mortality/Mortality | LC50 | 12 | days | 5000 | μg/L | × | 16 ECOTOX | Davis,H.C., and H. Hidu | Effects of Pesticides on Embryonic Development of Clams and Oysters and on Survival and Growth of the Larvae | Fish. Bull.67(2) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Mortality/Mortality | LC50 | 96 | hours | 17.9 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Chironomus tentans | Behavior/Swimming | EC50 | 96 | hours | 1000 | μg/L | × | 16 ECOTOX | Lydy,M.J., and K.R. Austin | Toxicity Assessment of Pesticide Mixtures Typical of the Sacramento-San Joaquin Delta Using Chironomus tentans | Arch. Environ. Contam. Toxicol.48(1) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Mortality/Mortality | LC50 | 2 | hours | 1000 | μg/L | × | 16 ECOTOX | Tsunemasa,N., and H. Okamura | Effects of Organotin Alternative Antifoulants on Oyster Embryo | Arch. Environ. Contam. Toxicol.61(1) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Mortality/Mortality | LC50 | 96 | hours | 400 | μg/L | × | 16 ECOTOX | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126 | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Mortality/Survival | LOEC | 7 | days | 7.7 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Reproduction/Progeny counts/numbers | LOEC | 7 | days | 7.7 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Mortality/Mortality | NR-ZERO | 8 | days | 10 | μg/L | × | 16 ECOTOX | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Mortality/Survival | NOEC | 7 | days | 4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Mortality/Mortality | LC50 | 7 | days | 7.1 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Mortality/Mortality | NR-LETH | 7 | days | 17.8 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Reproduction/Progeny counts/numbers | NOEC | 7 | days | 4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | LC50 | 3 | hours | >40000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2018/03/16 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Reproduction | LOEC | 7 | days | 7700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | LC50 | 4 | days | 17900 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | LC50 | 7 | days | 7100 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | NOEC | 7 | days | 4000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Reproduction | NOEC | 7 | days | 4000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | 7 | days | 17800 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | ||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | LOEC | 7 | days | 7700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Mortality | 8 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | |||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 2 | days | 2000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11): 2516-2524 | 2003 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Mortality | LC50 | 4 | days | 400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126:105-109 | 1974 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 2 | days | 8600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2:1115-1120 | 2002 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | LOEC | 2 | days | 3500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Physiology | EC50 | 2 | days | 1700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 2 | days | 8400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 2 | days | 8600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., M. Ejerhoon, A.R. Fernandez-Alba, and Y. Chisti | Combined Toxicity Effects of MTBE and Pesticides Measured with Vibrio fischeri and Daphnia magna Bioassays | Water Res.37(17): 4091-4098 | 2003 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Physiology | EC50 | 1 | days | 1200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 2 | days | 8600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Mortality | NOEL | 8 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | NOEL | 2 | days | <5000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Reproduction | NOEL | 8 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Physiology | EC50 | 1.08 | days | 47000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Crosby,D.G., and R.K. Tucker | Toxicity of Aquatic Herbicides to Daphnia magna | Science154:289-291 | 1966 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Physiology | EC50 | 1 | days | 2300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2017/03/15 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Physiology | EC50 | 2 | days | 1000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2017/03/15 | ||||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 2 | days | 8600 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., M. Ejerhoon, A.R. Fernandez-Alba, and Y. Chisti | Combined Toxicity Effects of MTBE and Pesticides Measured with Vibrio fischeri and Daphnia magna Bioassays | Water Res.37(17): 4091-4098 | 2003 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication | EC50 | 2 | days | 1000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication | EC50 | 2 | days | 1700 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 2 | days | 8400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 2 | days | 2000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11): 2516-2524 | 2003 | 2018/03/16 | |||||
| 甲殻類 | Ceriodaphnia dubia | Mortality | 8 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/07 | ||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Intoxication | EC50 | 2 | days | 1400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Population | 21 | days | <=4000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Kersting,K. | Effects of Diuron on the Energy Budget of a Daphnia magna Population | In: J.H.Koeman and J.J.T.W.A.Strik (Eds.), Sublethal Effects of Toxic Chemicals on Aquatic Animals, Elsevier Sci.Publ., Amsterdam, NY:159-166 | 1975 | 2016/03/25 | |||||||
| 甲殻類 | Daphnia magna | Reproduction | 50~250 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Shcherban,E.P. | The Effect of Low Concentrations of Pesticides on the Development of Some Cladocera and the Abundance of Their Progeny | Hydrobiol. J.6(6): 85-89 | 1972 | 2016/03/25 | ||||||||||
| 甲殻類 | Daphnia magna | Mortality | 21 | days | <=4000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Kersting,K. | Effects of Diuron on the Energy Budget of a Daphnia magna Population | In: J.H.Koeman and J.J.T.W.A.Strik (Eds.), Sublethal Effects of Toxic Chemicals on Aquatic Animals, Elsevier Sci.Publ., Amsterdam, NY:159-166 | 1975 | 2016/03/25 | |||||||
| 甲殻類 | Daphnia magna | Growth | 50~250 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Shcherban,E.P. | The Effect of Low Concentrations of Pesticides on the Development of Some Cladocera and the Abundance of Their Progeny | Hydrobiol. J.6(6): 85-89 | 1972 | 2016/03/25 | ||||||||||
| 甲殻類 | Nitocra spinipes | Mortality | LC50 | 4 | days | 4000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Karlsson,J., M. Breitholtz, and B. Eklund | A Practical Ranking System to Compare Toxicity of Anti-Fouling Paints | Mar. Pollut. Bull.52(12): 1661-1667 | 2006 | 2018/03/16 | |||||
| 甲殻類 | Penaeus aztecus | Intoxication | NOEC | 2 | days | 1000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Butler,P.A. | Effects of Herbicides on Estuarine Fauna | Proc. South. Weed Conf.18:576-580 | 1965 | 2018/03/16 | |||||
| 甲殻類 | Daphnia magna | Mortality | LC50 | 4 | days | 400 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126:105-109 | 1974 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | LOEC | 2 | days | 3500 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | NOEL | 2 | days | <5000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Reproduction | NOEL | 8 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication | EC50 | 1 | days | 1200 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Mortality | NOEL | 8 | days | 10 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/07 | |||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication | EC50 | 1 | days | 2300 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1): 53-59 | 1998 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 2 | days | 8600 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2:1115-1120 | 2002 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 2 | days | 8600 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2): 358-366 | 2005 | 2018/03/07 | |||||
| 甲殻類 | Daphnia magna | Intoxication | EC50 | 1.1 | days | 47000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Crosby,D.G., and R.K. Tucker | Toxicity of Aquatic Herbicides to Daphnia magna | Science154:289-291 | 1966 | 2018/03/07 | |||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Lethal | NOEC | 7 | days | 4 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 甲殻類 | Daphnia pulex | mortality | LC50 | 7 | days | 7.1 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Chironomus tentans | mortality, growth | NOEC | 10 | days | 3.4 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Chironomus tentans | Mortality/Mortality | NR-LETH | 10 | days | 7.1 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | mortality | LC50 | 96 | hours | 17.9 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Chironomus tentans | Mortality/Mortality | LC50 | 10 | days | 3.3 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Chironomus tentans | mortality | LC50 | 10 | days | 3.3 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Chironomus tentans | Growth/Wet weight (AQUIRE only) | LOEC | 10 | days | 7.1 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Chironomus tentans | Growth/Wet weight (AQUIRE only) | NOEC | 10 | days | 3.4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | mortality | NOEC | 7 | days | 4 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Chironomus tentans | Mortality/Survival | NOEC | 10 | days | 3.4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Chironomus tentans | Mortality/Survival | LOEC | 10 | days | 3.4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 甲殻類 | Chironomus tentans | mortality | NOEC | 10 | days | 1.9 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Lethal | EC50 | 7 | days | 7.1 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Lethal | LOEC | 7 | days | 7.7 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Lethal | EC50 | 96 | hours | 17.9 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Rhodes ea 95 | 2017/03/01 | |||||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 22.6 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 2008 | 2017/01/27 | ||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 24 | hours | >32 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 2008 | 2017/01/27 | ||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 1.4 | mg/L | × | 12 ECHA Information on Registered Substances | 2 | study report | 1983 | 2018/02/07 | ||||||
| 甲殻類 | Crassostrea virginica | NOEL | 96 | hours | <2.4 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Core | 2021/02/17 | ||||||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 1.4 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 26 | hours | 47000 | μg/L | × | 16 ECOTOX | Crosby,D.G., and R.K. Tucker | Toxicity of Aquatic Herbicides to Daphnia magna | Science154 | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea virginica | EC50 | 96 | hours | 1800 | ppb | 3 USEPA Pesticide Ecotoxicity Database | Core | 2021/02/17 | ||||||||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication/Immobile | EC50 | 24 | hours | 1200 | μg/L | × | 16 ECOTOX | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 24 | hours | >32 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 22.6 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Crassostrea virginica | EC50 | 96 | hours | 4.8 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Core | 2021/02/17 | ||||||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 1.4 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 2 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 24 | hours | >32 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | mobility | EC50 | 48 | hours | 22.6 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | Mortality | LC50 | 48 | hours | 1.4 | mg/L | 17 Aquatic OASIS (OECD QSAR Toolbox) | Ohe, P.C. von der, Kühne, R., Ebert, R.-U., Altenburger, R., Liess, M., and Schüürmann G. | Structural Alerts-A New Classification Model to Discriminate Excess Toxicity from Narcotic Effect Levels of Organic Compounds in the Acute Daphnid Assay | Chem. Res. Toxicol., 18 (3), 536 -555. | 2005 | 2017/03/22 | ||||||
| 甲殻類 | Daphnia magna | EC50 | 48 | hours | >17100 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 ジウロン(DCMU) | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 甲殻類 | Daphnia magna | EC50 | 48 | hours | 1900 | μg/L | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | ||||||||
| 甲殻類 | Crassostrea virginica | Morphology/Shell deposition | EC50 | 96 | hours | 1.8 | ppm | × | 16 ECOTOX | Butler,P.A. | Effects of Herbicides on Estuarine Fauna | Proc. South. Weed Conf.18 | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 48 | hours | 7.2 | mg/L | × | 16 ECOTOX | Sanchis,J., M. Olmos, P. Vincent, M. Farre, and D. Barcelo | New Insights on the Influence of Organic Co-Contaminants on the Aquatic Toxicology of Carbon Nanomaterials | Environ. Sci. Technol.50(2) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 48 | hours | 8.6 | mg/L | × | 16 ECOTOX | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2) | 2020/11/16 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication/Immobile | EC50 | 48 | hours | 1000 | μg/L | × | 16 ECOTOX | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 48 | hours | 8.6 | mg/L | × | 16 ECOTOX | Fernandez-Alba,A.R., L. Piedra, M. Mezcua, and M.D. Hernando | Toxicity of Single and Mixed Contaminants in Seawater Measured with Acute Toxicity Bioassays | Sci. World J.2 | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea virginica | Intoxication/Immobile | NOEL | 96 | hours | 2.4 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Crassostrea virginica | Growth/Growth, general | EC50 | 96 | hours | 1800 | μg/L | × | 16 ECOTOX | Butler,P.A. | Commercial Fishery Investigations | In: Pesticide-Wildlife Studies, 1963, U.S.D.I., Fish and Wildl.Serv.,Circ.199 | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Mortality/Mortality | LC10 | 24 | hours | 1000 | μg/L | × | 16 ECOTOX | Tsunemasa,N., and H. Okamura | Effects of Organotin Alternative Antifoulants on Oyster Embryo | Arch. Environ. Contam. Toxicol.61(1) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 48 | hours | 2 | mg/L | × | 16 ECOTOX | Malato,S., J. Caceres, A.R. Fernandez-Alba, L. Piedra, M.D. Hernando, A. Aguera, and J. Vial | Photocatalytic Treatment of Diuron by Solar Photocatalysis: Evaluation of Main Intermediates and Toxicity | Environ. Sci. Technol.37(11) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Development/Abnormal | LOEC | 24 | hours | 0.01 | μg/L | × | 16 ECOTOX | Behrens,D., J. Rouxel, T. Burgeot, and F. Akcha | Comparative Embryotoxicity and Genotoxicity of the Herbicide Diuron and Its Metabolites in Early Life Stages of Crassostrea gigas: Implication of Reactive Oxygen Species Production | Aquat. Toxicol.175 | 2020/11/16 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication/Immobile | EC50 | 48 | hours | 1700 | μg/L | × | 16 ECOTOX | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1) | 2020/11/16 | ||||||
| 甲殻類 | Ceriodaphnia dubia | Intoxication/Immobile | EC50 | 24 | hours | 2300 | μg/L | × | 16 ECOTOX | Foster,S., M. Thomas, and W. Korth | Laboratory-Derived Acute Toxicity of Selected Pesticides to Ceriodaphnia dubia | Australas. J. Ecotoxicol.4(1) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Development/Abnormal | LOEC | 24 | hours | 0.05 | μg/L | × | 16 ECOTOX | Behrens,D., J. Rouxel, T. Burgeot, and F. Akcha | Comparative Embryotoxicity and Genotoxicity of the Herbicide Diuron and Its Metabolites in Early Life Stages of Crassostrea gigas: Implication of Reactive Oxygen Species Production | Aquat. Toxicol.175 | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Development/Abnormal | LOEC | 24 | hours | 0.5 | μg/L | × | 16 ECOTOX | Behrens,D., J. Rouxel, T. Burgeot, and F. Akcha | Comparative Embryotoxicity and Genotoxicity of the Herbicide Diuron and Its Metabolites in Early Life Stages of Crassostrea gigas: Implication of Reactive Oxygen Species Production | Aquat. Toxicol.175 | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | EC50 | 48 | hours | 8.6 | mg/L | × | 16 ECOTOX | Hernando,M.D., M. Ejerhoon, A.R. Fernandez-Alba, and Y. Chisti | Combined Toxicity Effects of MTBE and Pesticides Measured with Vibrio fischeri and Daphnia magna Bioassays | Water Res.37(17) | 2020/11/16 | ||||||
| 甲殻類 | Daphnia pulex | Intoxication/Immobile | EC50 | 48 | hours | 1.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 甲殻類 | Mercenaria mercenaria | Development/Developmental changes, general | EC50 | 48 | hours | 2530 | μg/L | × | 16 ECOTOX | Davis,H.C., and H. Hidu | Effects of Pesticides on Embryonic Development of Clams and Oysters and on Survival and Growth of the Larvae | Fish. Bull.67(2) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea virginica | Intoxication/Immobile | EC50 | 96 | hours | 4.8 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Crassostrea gigas | Mortality/Mortality | LC50 | 24 | hours | 1000 | μg/L | × | 16 ECOTOX | Tsunemasa,N., and H. Okamura | Effects of Organotin Alternative Antifoulants on Oyster Embryo | Arch. Environ. Contam. Toxicol.61(1) | 2020/11/16 | ||||||
| 甲殻類 | Crassostrea gigas | Development/Abnormal | NOEC | 24 | hours | 0.002 | μg/L | × | 16 ECOTOX | Behrens,D., J. Rouxel, T. Burgeot, and F. Akcha | Comparative Embryotoxicity and Genotoxicity of the Herbicide Diuron and Its Metabolites in Early Life Stages of Crassostrea gigas: Implication of Reactive Oxygen Species Production | Aquat. Toxicol.175 | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | EC50 | 48 | hours | 8.4 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Core | 2021/03/12 | ||||||||||
| 甲殻類 | Daphnia pulex | Mortality | LC50 | 48 | hours | 0.00000603 | mol/L | 17 Aquatic OASIS (OECD QSAR Toolbox) | Ohe, P.C. von der, Kühne, R., Ebert, R.-U., Altenb | Structural Alerts-A New Classification Model to Di | Chem. Res. Toxicol., 18 (3), 536 -555. | 2005 | 2023/03/14 | ||||||
| 甲殻類 | Mysidopsis bahia | Mortality | EC50 | 96 | hours | 1.1 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 甲殻類 | Nitocra spinipes | Mortality/Mortality | LC50 | 96 | hours | 4000 | μg/L | × | 16 ECOTOX | Karlsson,J., M. Breitholtz, and B. Eklund | A Practical Ranking System to Compare Toxicity of Anti-Fouling Paints | Mar. Pollut. Bull.52(12) | 2020/11/16 | ||||||
| 甲殻類 | Penaeus aztecus | Multiple/Multiple effects reported as one result | NOEC | 48 | hours | 1000 | μg/L | × | 16 ECOTOX | Butler,P.A. | Commercial Fishery Investigations | In: Circular 226, Effects of Pesticides on Fish and Wildl., U.S.D.I., Washington, DC | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | NOEL | 48 | hours | <5 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Core | 2021/03/12 | ||||||||||
| 甲殻類 | Americamysis bahia | Mortality/Mortality | LC50 | 96 | hours | 1.1 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Penaeus aztecus | Intoxication/Immobile | NOEC | 48 | hours | 1 | ppm | × | 16 ECOTOX | Butler,P.A. | Effects of Herbicides on Estuarine Fauna | Proc. South. Weed Conf.18 | 2020/11/16 | ||||||
| 甲殻類 | Daphnia magna | Intoxication/Immobile | LOEC | 48 | hours | 3.5 | mg/L | × | 16 ECOTOX | Hernando,M.D., A.R. Fernandez-Alba, R. Tauler, and D. Barcelo | Toxicity Assays Applied to Wastewater Treatment | Talanta65(2) | 2020/11/16 | ||||||
| 甲殻類 | Americamysis bahia | Mortality/Mortality | NOEL | 96 | hours | 0.6 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Penaeus aztecus | Multiple/Multiple effects reported as one result | NOEC | 24 | hours | 1 | ppm | × | 16 ECOTOX | Butler,P.A. | Commercial Fishery Investigations | In: Circular 226, Effects of Pesticides on Fish and Wildl., U.S.D.I., Washington, DC | 2020/11/16 | ||||||
| 甲殻類 | Penaeus aztecus | LC50 | 48 | hours | >1000 | ppb | 3 USEPA Pesticide Ecotoxicity Database | F.L. Mayer | 1986 | 2018/02/20 | |||||||||
| 甲殻類 | Mysidopsis bahia | LC50 | 96 | hours | 1.1 | ppm | 3 USEPA Pesticide Ecotoxicity Database | G. Susanke | 1991 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | EC50 | 48 | hours | 8.4 | ppb | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1992 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia sp. Daphnia pulex | EC50 | 48 | hours | 1.4 | ppb | 3 USEPA Pesticide Ecotoxicity Database | Johnson & Finley | 1980 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | >=1 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1989 | 2017/01/27 | ||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | >1 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1989 | 2017/01/27 | ||||||
| 甲殻類 | Daphnia magna | NOEL | 48 | hours | <5 | ppm | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1992 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | effect on body weight of parent animal | NOEC | 21 | days | 0.1 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1996 | 2018/02/07 | ||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | 0.97 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1996 | 2018/02/07 | ||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | 0.56 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1996 | 2018/02/07 | ||||||
| 甲殻類 | Daphnia magna | NOEL | 21 | days | 0.057 | ppm | 3 USEPA Pesticide Ecotoxicity Database | R. Lee | 2008 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | LOEC | 28 | days | >0.2 | ppm | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola/ | 1982 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | effect on body weight of parent animal | LOEC | 21 | days | 0.17 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1996 | 2018/02/07 | ||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | 0.97 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | effect on body weight of parent animal | NOEC | 21 | days | 0.1 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | >1 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | >=1 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | effect on body weight of parent animal | LOEC | 21 | days | 0.17 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | 0.56 | mg/L | 12 ECHA Information on Registered Substances | study report | 2021/03/02 | |||||||||
| 甲殻類 | Daphnia magna | weight (parent animal) | LOEC | 21 | days | 0.17 | mg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | >=1 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | weight (parent animal) | NOEC | 21 | days | 0.1 | mg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | 0.97 | mg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | reproduction | NOEC | 21 | days | 0.56 | mg/L | meas. (initial), test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Daphnia magna | LOEC | 21 | days | 0.113 | ppm | 3 USEPA Pesticide Ecotoxicity Database | R. Lee | 2008 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | Growth | NOEC | 21 | days | 0.096 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 甲殻類 | Daphnia magna | NOEL | 28 | days | 0.2 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Supplemental | 2021/04/07 | ||||||||||
| 甲殻類 | Americamysis bahia | Growth/Growth, general | LOEC | 28 | days | 0.56 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Daphnia magna | LOEC | 28 | days | >0.2 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Supplemental | 2021/04/07 | ||||||||||
| 甲殻類 | Americamysis bahia | Reproduction/Progeny counts/numbers | LOEC | 28 | days | 1.9 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Americamysis bahia | Reproduction/Hatch | LOEC | 28 | days | 1.9 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Americamysis bahia | Growth/Growth, general | NOEC | 28 | days | 0.27 | ppm | 16 ECOTOX | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C. | 2020/11/16 | |||||||
| 甲殻類 | Daphnia magna | reproduction | LOEC | 21 | days | >1 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 甲殻類 | Mysidopsis bahia | NOEL | 28 | days | 0.27 | ppm | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1993 | 2018/02/20 | |||||||||
| 甲殻類 | Mysidopsis bahia | NOEL | 96 | hours | <0.6 | ppm | 3 USEPA Pesticide Ecotoxicity Database | G. Susanke | 1991 | 2018/02/20 | |||||||||
| 甲殻類 | Daphnia magna | NOEL | 28 | days | 0.2 | ppm | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola/ | 1982 | 2018/02/20 | |||||||||
| 甲殻類 | Mysidopsis bahia | LOEC | 28 | days | 0.56 | ppm | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1993 | 2018/02/20 | |||||||||
| 魚類 | Pimephales promelas | Development/Normal | LOEC | 33.4 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||||
| 魚類 | Oryzias latipes (Japanese medaka) | Mortality/Mortality | LOEC | 15 | days | 8.6 | μM | × | 16 ECOTOX | Newman,J.W., D.L. Denton, C. Morisseau, C.S. Koger, C.E. Wheelock, D.E. Hinton, and B.D. Hammock | Evaluation of Fish Models of Soluble Epoxide Hydrolase Inhibition | Environ. Health Perspect.109(1) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality/Mortality | LC50 | 196 | hours | 7.7 | mg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Oryzias latipes (Japanese medaka) | Development/Developmental changes, general | LOEC | 15 | days | 32 | μM | × | 16 ECOTOX | Newman,J.W., D.L. Denton, C. Morisseau, C.S. Koger, C.E. Wheelock, D.E. Hinton, and B.D. Hammock | Evaluation of Fish Models of Soluble Epoxide Hydrolase Inhibition | Environ. Health Perspect.109(1) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Development/Normal | MATC | 22 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||||
| 魚類 | Pimephales promelas | Development/Abnormal | MATC | 5 | days | >33.4~78 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Development/Normal | NOEC | 14.5 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||||
| 魚類 | Danio rerio (Zebrafish) | Development/Abnormal | LOEC | 114 | hours | 10 | μM | × | 16 ECOTOX | Wang,P., Z. Wang, P. Xia, and X. Zhang | Concentration-Dependent Transcriptome of Zebrafish Embryo for Environmental Chemical Assessment | Chemosphere245 | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Growth/Wet weight (AQUIRE only) | NOEC | 10 | days | 3.4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality/Mortality | NR-LETH | 7 | days | 31.2 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 28 | days | 0.23 | mg/L | × | 16 ECOTOX | Okamura,H., T. Watanabe, I. Aoyama, and M. Hasobe | Toxicity Evaluation of New Antifouling Compounds Using Suspension-Cultured Fish Cells | Chemosphere46(7) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Growth/Wet weight (AQUIRE only) | LOEC | 10 | days | 3.4 | mg/L | ○ | 16 ECOTOX | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3) | 2020/11/16 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Development/Abnormal | NOEC | 114 | hours | 3 | μM | × | 16 ECOTOX | Wang,P., Z. Wang, P. Xia, and X. Zhang | Concentration-Dependent Transcriptome of Zebrafish Embryo for Environmental Chemical Assessment | Chemosphere245 | 2020/11/16 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Mortality/Mortality | LD50 | 114 | hours | 29.96 | μM | × | 16 ECOTOX | Wang,P., Z. Wang, P. Xia, and X. Zhang | Concentration-Dependent Transcriptome of Zebrafish Embryo for Environmental Chemical Assessment | Chemosphere245 | 2020/11/16 | ||||||
| 魚類 | Oryzias latipes (Japanese medaka) | Development/Developmental changes, general | NOEC | 15 | days | 8.6 | μM | × | 16 ECOTOX | Newman,J.W., D.L. Denton, C. Morisseau, C.S. Koger, C.E. Wheelock, D.E. Hinton, and B.D. Hammock | Evaluation of Fish Models of Soluble Epoxide Hydrolase Inhibition | Environ. Health Perspect.109(1) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 2 | days | 19900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 9500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | >25000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 84000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Biochemical | EC50 | 4 | days | 12 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Newman,J.W., D.L. Denton, C. Morisseau, C.S. Koger, C.E. Wheelock, D.E. Hinton, and B.D. Hammock | Evaluation of Fish Models of Soluble Epoxide Hydrolase Inhibition | Environ. Health Perspect.109(1): 61-66 | 2001 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 6400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 8400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 8.17 | days | 7700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | EC50 | 2 | days | 7400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3:33-44 | 1966 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 35000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Cyprinus carpio (Carp) | Mortality | LC50 | 2 | days | 3200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 38800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Cyprinus carpio (Carp) | Mortality | LC50 | 4 | days | 2900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126:105-109 | 1974 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 3600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 4900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 10 | days | 27100 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 12000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 7600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Carassius auratus (Goldfish) | Mortality | LC50 | 2 | days | 5800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geiger,D.L., S.H. Poirier, L.T. Brooke, and D.J. Call | Acute Toxicities of Organic Chemicals to Fathead Minnows (Pimephales promelas) Volume III | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:328 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 3200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 7 | days | 11700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 4000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 12500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 9700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 9000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 8400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 1 | days | 23300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | EC50 | 2 | days | 4300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3:33-44 | 1966 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 29800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 16700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 5900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 7000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oryzias latipes (Japanese medaka) | Mortality | LC50 | 2 | days | 3500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 2 | days | 7400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 9300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 2800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 5900 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA:405-418 | 1974 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 27000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 1950 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Cellular Effects | NOEC | 7 | days | 0.205 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Crago,J., K. Tran, A. Budicin, B. Schreiber, R. Lavado, and D. Schlenk | Exploring the Impacts of Two Separate Mixtures of Pesticide and Surfactants on Estrogenic Activity in Male Fathead Minnows and Rainbow Trout | Arch. Environ. Contam. Toxicol.68:362-370 | 2015 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEL | 7 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 17000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | NOEC | 7 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | NOEC | 7 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 60 | days | 61.8 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 10 | days | 3400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 7 | days | 8300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | NOEC | 60 | days | 26.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | LOEC | 38 | days | <440 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | |||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | LOEC | 38 | days | 440 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 10 | days | <3400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 63 | days | 78 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 5 | days | 78 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LOEC | 10 | days | 27100 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 21 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 21 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | 7 | days | 31200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | |||||||
| 魚類 | Danio rerio (Zebrafish) | Mortality | 21 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | |||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 10 | days | 20000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 63 | days | 33.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | NOEC | 7 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEL | 7 | days | 10 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 15500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 2 | days | 4300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA:405-418 | 1974 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 9400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 63 | days | 51 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | |||||||
| 魚類 | Oryzias latipes (Japanese medaka) | Biochemical | NOEC | 7 | days | 0.205 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schlenk,D., R. Lavado, J.E. Loyo-Rosales, W. Jones, L. Maryoung, N. Riar, I. Werner, and D. Sedlak | Reconstitution Studies of Pesticides and Surfactants Exploring the Cause of Estrogenic Activity Observed in Surface Waters of the San Francisco Bay Delta | Environ. Sci. Technol.46(16): 9106-9111 | 2012 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 13400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 63 | days | 78 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 14 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 19600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 60 | days | 26.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 11500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 4200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 7 | days | 4200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2017/03/15 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | LOEC | 38 | days | <440 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 63 | days | 51 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 9000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 27000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 4000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 2 | days | 7400 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 4200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 12500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Development | NOEC | 5 | days | 33.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | LOEC | 60 | days | 61.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 11500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 5300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | 63 | days | 51 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 5 | days | 29 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | LOEC | 38 | days | 440 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 38800 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 9400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 10 | days | 20000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 7 | days | 4200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | NOEC | 60 | days | 26.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 5900 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA:405-418 | 1974 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | NOEC | 60 | days | 26.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 6400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LOEC | 60 | days | 61.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 16700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | LOEC | 60 | days | 61.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 12000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC:51-63 | 1965 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 21 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Geiger,D.L., S.H. Poirier, L.T. Brooke, and D.J. Call | Acute Toxicities of Organic Chemicals to Fathead Minnows (Pimephales promelas) Volume III | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:328 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 8400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 2 | days | 19900 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 10 | days | 27100 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 28 | days | 230 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Okamura,H., T. Watanabe, I. Aoyama, and M. Hasobe | Toxicity Evaluation of New Antifouling Compounds Using Suspension-Cultured Fish Cells | Chemosphere46(7): 945-951 | 2002 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 35000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 63 | days | 78 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 60 | days | 26.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Genetic | NOEC | 7 | days | 0.205 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Crago,J., K. Tran, A. Budicin, B. Schreiber, R. Lavado, and D. Schlenk | Exploring the Impacts of Two Separate Mixtures of Pesticide and Surfactants on Estrogenic Activity in Male Fathead Minnows and Rainbow Trout | Arch. Environ. Contam. Toxicol.68:362-370 | 2015 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 71000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 9300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 14 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 7 | days | 11700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 21 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 63 | days | 78 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Development | LOEC | 5 | days | 78 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LOEC | 10 | days | 27100 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 3500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 10 | days | 3400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 7 | days | 8300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 8400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 16000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 6200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8600 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oryzias latipes (Japanese medaka) | Mortality | LC50 | 2 | days | 3500 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | NOEC | 7 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 2 | days | 4300 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA:405-418 | 1974 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 13400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 60 | days | 26.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 63 | days | 33.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 71000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 28 | days | 230 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Okamura,H., T. Watanabe, I. Aoyama, and M. Hasobe | Toxicity Evaluation of New Antifouling Compounds Using Suspension-Cultured Fish Cells | Chemosphere46(7): 945-951 | 2002 | 2017/03/15 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Growth | LOEC | 38 | days | 440 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 14 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 7700 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | LOEC | 60 | days | 61.8 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 14 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 16000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | 63 | days | 51 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | |||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 5 | days | >33.4~<78 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 63 | days | 51 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2017/03/15 | |||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LOEC | 60 | days | 61.8 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 3500 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Cellular Effects | LOEC | 21 | days | 1 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 5 | days | 29 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | LOEC | 60 | days | 61.8 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 5 | days | 33.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Reproduction | NOEC | 60 | days | 26.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEC | 60 | days | 26.4 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 23800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 6200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 5300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2017/03/15 | ||||||
| 魚類 | Carassius auratus (Goldfish) | Biochemical | LOEL | 12 | hours | 5 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bretaud,S., J.P. Toutant, and P. Saglio | Effects of Carbofuran, Diuron, and Nicosulfuron on Acetylcholinesterase Activity in Goldfish (Carassius auratus) | Ecotoxicol. Environ. Saf.47(2): 117-124 | 2000 | 2017/03/15 | ||||||
| 魚類 | Carassius auratus (Goldfish) | Behavior | 1 | days | 0.5~50 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Saglio,P., and S. Trijasse | Behavioral Responses to Atrazine and Diuron in Goldfish | Arch. Environ. Contam. Toxicol.35(3): 484-491 | 1998 | 2016/03/25 | ||||||||
| 魚類 | Cyprinus carpio (Carp) | Cellular Effects | 10000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Lakota,S., A. Raszka, J. Roszkowski, S. Hlond, F. Kozlowski, and J. Stefan | Examinations of the Toxicity of Diuron, Linuron, Monolinuron and Monuron for the Carp Fry in the Acute Test | Med. Weter.34(1): 20-22 | 1977 | 2016/03/25 | |||||||||
| 魚類 | Cyprinus carpio (Carp) | Cellular Effects | 40 | days | 100 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schulz,D. | Proliferative Endocarditis in the Heart of Carps After Exposure to the Herbicide Karmex | Zentbl. Vetmed. Reihe A19(5): 390-406 | 1972 | 2016/03/25 | |||||||
| 魚類 | Danio rerio (Zebrafish) | No Group Code | 5 | days | 80 | μM | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Padilla,S., D. Corum, B. Padnos, D.L. Hunter, A. Beam, K.A. Houck, N. Sipes, N. Kleinstreuer, T. Knudsen, D.J. Dix, and | Zebrafish Developmental Screening of the ToxCast Phase I Chemical Library | Reprod. Toxicol.33(2): 174-187 | 2012 | 2016/03/25 | |||||||
| 魚類 | Carassius auratus (Goldfish) | Behavior | 0.17 | hours | 100~10000 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Saglio,P., and S. Trijasse | Behavioral Responses to Atrazine and Diuron in Goldfish | Arch. Environ. Contam. Toxicol.35(3): 484-491 | 1998 | 2016/03/25 | ||||||||
| 魚類 | Leuciscus idus (Orfe) | Growth | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Nature of the Action of Some Herbicides on Carp | Nauchn. Osn. Okhr. Prir.3:153-171 | 1975 | 2016/03/25 | ||||||||||
| 魚類 | Leuciscus idus (Orfe) | Reproduction | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Nature of the Action of Some Herbicides on Carp | Nauchn. Osn. Okhr. Prir.3:153-171 | 1975 | 2016/03/25 | ||||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | 7 | days | 1000~15100 | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2016/03/25 | ||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 7 | days | 8300 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2016/03/25 | |||||||
| 魚類 | Leuciscus idus (Orfe) | Biochemical | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Nature of the Action of Some Herbicides on Carp | Nauchn. Osn. Okhr. Prir.3:153-171 | 1975 | 2016/03/25 | ||||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 7 | days | 4200 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2016/03/25 | |||||||
| 魚類 | Leuciscus idus (Orfe) | Mortality | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Nature of the Action of Some Herbicides on Carp | Nauchn. Osn. Okhr. Prir.3:153-171 | 1975 | 2016/03/25 | ||||||||||
| 魚類 | Leuciscus idus (Orfe) | Mortality | 76.1 | days | <=400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Pathomorphological Changes in Erythrocytes in Fish During Chronic Diuron Poisoning | Vliyamie Pestits, Dikikh. Zhivotn.:12-18 | 1972 | 2016/03/25 | |||||||
| 魚類 | Leuciscus idus (Orfe) | Biochemical | 76.1 | days | <=400 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Pathomorphological Changes in Erythrocytes in Fish During Chronic Diuron Poisoning | Vliyamie Pestits, Dikikh. Zhivotn.:12-18 | 1972 | 2016/03/25 | |||||||
| 魚類 | Leuciscus idus (Orfe) | Biochemical | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Popova,G.V. | Nature of the Action of Some Herbicides on Carp | Nauchn. Osn. Okhr. Prir.3:153-171 | 1975 | 2016/03/25 | ||||||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | NOEL | 4 | days | 3600 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/16 | |||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | LC50 | 4 | days | 6700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/16 | |||||
| 魚類 | Cyprinus carpio (Carp) | Mortality | LC50 | 2 | days | 3200 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 5900 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | NOEC | 7 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | NOEC | 7 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 63 | days | 33.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | 7 | days | 31200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEL | 7 | days | 10 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 8.2 | days | 7700 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Oryzias latipes (Japanese medaka) | Biochemical | NOEC | 7 | days | 0.205 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Schlenk,D., R. Lavado, J.E. Loyo-Rosales, W. Jones, L. Maryoung, N. Riar, I. Werner, and D. Sedlak | Reconstitution Studies of Pesticides and Surfactants Exploring the Cause of Estrogenic Activity Observed in Surface Waters of the San Francisco Bay Delta | Environ. Sci. Technol.46(16): 9106-9111 | 2012 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 7000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | EC50 | 2 | days | 4300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3:33-44 | 1966 | 2018/03/16 | |||||
| 魚類 | Cyprinus carpio (Carp) | Mortality | LC50 | 4 | days | 2900 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126:105-109 | 1974 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 9500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 21 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Growth | LOEC | 38 | days | 440 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 63 | days | 33.4 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | NOEL | 7 | days | 10 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Huang,X., S. Fong, L. Deanovic, and T.M. Young | Toxicity of Herbicides in Highway Runoff | Environ. Toxicol. Chem.24(9): 2336-2340 | 2005 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | >25000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8900 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 84000 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Mortality | 21 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | 63 | days | 51 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI:318 p. | 1992 | 2018/03/07 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 19600 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 4 | days | 14200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 17000 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Enzyme | EC50 | 4 | days | 12 | μM | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Newman,J.W., D.L. Denton, C. Morisseau, C.S. Koger, C.E. Wheelock, D.E. Hinton, and B.D. Hammock | Evaluation of Fish Models of Soluble Epoxide Hydrolase Inhibition | Environ. Health Perspect.109(1): 61-66 | 2001 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 3600 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 14 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Danio rerio (Zebrafish) | Genetic | LOEC | 14 | days | 1 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6): 421-428 | 2010 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | LOEC | 60 | days | 61.8 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 7600 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | EC50 | 2 | days | 7400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3:33-44 | 1966 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 2800 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 9700 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3): 174-183 | 1969 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 1 | days | 15500 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Development | 5 | days | >33.4~<78 | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||||
| 魚類 | Carassius auratus (Goldfish) | Mortality | LC50 | 2 | days | 5800 | μg/L | FORMULATION | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nishiuchi,Y., and Y. Hashimoto | Toxicity of Pesticide Ingredients to Some Fresh Water Organisms | Sci. Pest Control (Botyu-Kagaku)32(1): 5-11 | 1967 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 3200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth | NOEC | 10 | days | <3400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Nebeker,A.V., and G.S. Schuytema | Chronic Effects of the Herbicide Diuron on Freshwater Cladocerans, Amphipods, Midges, Minnows, Worms, and Snails | Arch. Environ. Contam. Toxicol.35(3): 441-446 | 1998 | 2018/03/07 | |||||
| 魚類 | Carassius auratus (Goldfish) | Biochemical | LOEL | 12 | hours | 5 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Bretaud,S., J.P. Toutant, and P. Saglio | Effects of Carbofuran, Diuron, and Nicosulfuron on Acetylcholinesterase Activity in Goldfish (Carassius auratus) | Ecotoxicol. Environ. Saf.47(2): 117-124 | 2000 | 2018/03/16 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 1950 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 23800 | μg/L | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | U.S. Environmental Protection Agency | Pesticide Ecotoxicity Database (Formerly: Environmental Effects Database (EEDB)) | Environmental Fate and Effects Division, U.S.EPA, Washington, D.C.: | 1992 | 2018/03/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 1 | days | 23300 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5): 607-613 | 1987 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 8200 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 4 | days | 4900 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 4 | days | 10400 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | 29800 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Lepomis macrochirus (Bluegill) | Mortality | LC50 | 1 | days | >30000 | μg/L | ACTIVE INGREDIENT | 16 US EPA AQUIRE (AQUatic toxicity Information REtrieval) | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC:505 p. | 1986 | 2018/03/07 | |||||
| 魚類 | Pimephales promelas (Fathead minnow) | Lethal | NOEC | 10 | days | 20 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth_b | NOEC | 7 | days | 4.2 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Pimephales promelas | mortality, growth | NOEC | 7 | days | 4.2 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 魚類 | Pimephales promelas | mortality | NOEC | 10 | days | 20 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 魚類 | Pimephales promelas | mortality | LC50 | 10 | days | 27.1 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 魚類 | Pimephales promelas | mortality | LC50 | 7 | days | 11.7 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker AV, Schuytema GS | Chronic effects of the herbicide diuron on freshwater cladocerans, amphipods, midges, minnows, worms and snails | Arch Environ Contam Toxicol 35 | 2020/12/23 | |||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Growth_b | LOEC | 7 | days | 8.3 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Lethal | EC50 | 7 | days | 11.7 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Lethal | EC50 | 10 | days | 27.1 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Lethal | LOEC | 10 | days | 27.1 | mg/L | 9 ECETOC Aquatic Toxicity, EAT | Nebeker and Schuytema 98 | 2017/03/01 | |||||||||
| 魚類 | Lepomis macrochirus (Bluegill) | LC50 | 96 | hours | >25 | ppm | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1992 | 2018/02/21 | |||||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | LC50 | 96 | hours | 6.7 | ppm | 3 USEPA Pesticide Ecotoxicity Database | G. Susanke | 1990 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | LC50 | 96 | hours | 1.95 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | LC100 | 96 | hours | 21.5 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | LC0 | 96 | hours | 10 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Lepomis macrochirus (Bluegill) | LC50 | 96 | hours | 2.8 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Mayer & Ellersieck | 1986 | 2018/02/21 | |||||||||
| 魚類 | Cyprinus carpio (Carp) | LC50 | 96 | hours | >35500 | μg/L | 水溶解度に基づく | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 魚類 | Lepomis macrochirus (Bluegill) | LC50 | 96 | hours | 3.2 | ppm | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | LC50 | 96 | hours | 14.7 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | LC50 | 96 | hours | 16 | ppm | 3 USEPA Pesticide Ecotoxicity Database | Johnson & Finley | 1980 | 2018/02/21 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | Mortality | LC50 | 96 | hours | 14 | mg/L | 17 Aquatic OASIS (OECD QSAR Toolbox) | Russom, C.L., Bradbury, S.P., Broderius, S.J., Drummond, R.A. and Hammermeister, D.E. | PREDICTING MODES OF TOXIC ACTION FROM CHEMICAL STRUCTURE: ACUTE TOXICITY IN THE FATHEAD MINNOW (PIMEPHALES PROMELAS) | Environmental Toxicology and Chemistry, Vol. 16, No. 5, pp. 948–967. | 1997 | 2017/03/22 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | LC50 | 96 | hours | 14200 | μg/L | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | ||||||||
| 魚類 | Cyprinus carpio (Carp) | LC50 | 96 | hours | >17100 | μg/L | 有効成分換算値 | 2 日本環境省 農薬登録保留基準(水産動植物) | 環境省 | 水産動植物の被害防止に係る農薬登録保留基準の設定に関する資料 | 中央環境審議会土壌農薬部会農薬小委員会(第34 回)資料 | 2018/03/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 9.5 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 30 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 7.2 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 7600 | μg/L | × | 16 ECOTOX | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3) | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 8.6 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 7.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 27 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 16.7 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 7 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 8 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 8.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 30 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 12000 | μg/L | × | 16 ECOTOX | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 6.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 9700 | μg/L | × | 16 ECOTOX | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3) | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 10 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 4.2 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 7.7 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 10.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 5900 | ppb | × | 16 ECOTOX | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA | 2020/11/16 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | LC50 | 96 | hours | 6.7 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 71 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 8.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Cyprinus carpio (Carp) | Mortality/Mortality | LC50 | 96 | hours | 2900 | μg/L | × | 16 ECOTOX | Knapek,R., and S. Lakota | Biological Testing to Determine Toxic Effects of Pesticides in Water (Einige Biotests zur Untersuchung der Toxischen Wirkung von Pestiziden im Wasser) | Tagungsber. Akad. Landwirtschaftswiss. DDR126 | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | EC50 | 48 | hours | 4300 | μg/L | ○ | 16 ECOTOX | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3 | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | EC50 | 48 | hours | 7400 | μg/L | ○ | 16 ECOTOX | Cope,O.B. | Contamination of the Freshwater Ecosystem by Pesticides | J. Appl. Ecol.3 | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 9 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 9.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 4.9 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 29.8 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Pimephales promelas | Mortality/Mortality | LC50 | 24 | hours | 23.3 | mg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 30 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 38.8 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 4000 | μg/L | × | 16 ECOTOX | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality | LC50 | 28 | days | 4.01 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 13.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 17000 | μg/L | × | 16 ECOTOX | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3) | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 48 | hours | 4300 | ppb | × | 16 ECOTOX | Mayer,F.L.,Jr. | Pesticides as Pollutants | In: B.G.Liptak (Ed.), Environmental Engineer's Handbook, Chilton Book Co., Radnor, PA | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 6.2 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 8.3 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 30 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 3.5 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 96 | hours | 5.3 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 5900 | μg/L | × | 16 ECOTOX | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality | LC50 | 96 | hours | 0.0000603 | mol/L | 17 Aquatic OASIS (OECD QSAR Toolbox) | Russom, C.L., Bradbury, S.P., Broderius, S.J., Dru | PREDICTING MODES OF TOXIC ACTION FROM CHEMICAL STR | Environmental Toxicology and Chemistry, Vol. 16, N | 1997 | 2023/03/14 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 3.6 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 8900 | μg/L | × | 16 ECOTOX | Macek,K.J., C. Hutchinson, and O.B. Cope | The Effects of Temperature on the Susceptibility of Bluegills and Rainbow Trout to Selected Pesticides | Bull. Environ. Contam. Toxicol.4(3) | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 12.5 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 11.5 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 10.4 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Pimephales promelas | Mortality/Mortality | LC50 | 48 | hours | 19.9 | mg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 35 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 48 | hours | 7400 | μg/L | × | 16 ECOTOX | Cope,O.B. | Sport Fishery Investigations | Fish and Wildlife Service Circular 226, Effects of Pesticides on Fish and Wildlife. Washington, DC | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | Mortality/Mortality | LC50 | 24 | hours | 15.5 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 24 | hours | 30 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 9.3 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Lepomis macrochirus | Mortality/Mortality | LC50 | 96 | hours | 8.2 | AI mg/L | 16 ECOTOX | Mayer,F.L.,Jr., and M.R. Ellersieck | Manual of Acute Toxicity: Interpretation and Data Base for 410 Chemicals and 66 Species of Freshwater Animals | USDI Fish and Wildlife Service, Publication No.160, Washington, DC | 2020/11/16 | |||||||
| 魚類 | Oncorhynchus mykiss | mortality | LC0 | 96 | hours | 10 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss | mortality | LC100 | 96 | hours | 21.5 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss | mortality | LC50 | 96 | hours | 14.7 | mg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | LC50 | 96 | hours | 23.8 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Lepomis macrochirus (Bluegill) | LC50 | 96 | hours | 84 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | LC50 | 96 | hours | 19.6 | ppm | 3 USEPA Pesticide Ecotoxicity Database | C. Rodriguez | 1992 | 2018/02/21 | |||||||||
| 魚類 | Pimephales promelas (Fathead minnow) | LC50 | 96 | hours | 14.2 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | LOEC | 28 | days | 0.79 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | LOEC | 38 | days | <0.44 | ppm | 3 USEPA Pesticide Ecotoxicity Database | D. Felthousen | 1993 | 2018/02/21 | |||||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | NOEL | 96 | hours | 3.6 | ppm | 3 USEPA Pesticide Ecotoxicity Database | G. Susanke | 1990 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | NOEC | 28 | days | 0.41 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | mortality | LC50 | 28 | days | 4.01 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Oncorhynchus mykiss | mortality | LOEC | 28 | days | 0.79 | mg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Danio rerio | number hatched | NOEC | 63 | days | 1 | μg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss | mortality | NOEC | 28 | days | 0.41 | mg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Danio rerio | number hatched | NOEC | 35 | days | 1 | μg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Pimephales promelas | Mortality/Survival | LOEC | 60 | days post-hatch | 78 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | body length, weight and mortality | LOEC | 28 | days | 0.79 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Pimephales promelas (Fathead minnow) | NOEL | 60 | days | 26.4 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 | |||||||||
| 魚類 | Oncorhynchus mykiss (Rainbow trout) | body weight, length and condition | NOEC | 28 | days | 0.41 | mg/L | ○ | 12 ECHA Information on Registered Substances | 1 | study report | 1993 | 2018/02/07 | ||||||
| 魚類 | Pimephales promelas | Growth/Length | MATC | 63 | days | 51 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality/Survival | MATC | 63 | days | 51 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality/Survival | MATC | 60 | days post-hatch | >33.4~78 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Mortality/Survival | NOEC | 60 | days post-hatch | 33.4 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Growth/Weight | MATC | 63 | days | 51 | μg/L | ○ | 16 ECOTOX | Call,D.J., and D.L. Geiger | Subchronic Toxicities of Industrial and Agricultural Chemicals to Fathead Minnows (Pimephales promelas). Volume I | Center for Lake Superior Environmental Studies, University of Wisconsin, Superior, WI | 2020/11/16 | ||||||
| 魚類 | Danio rerio (Zebrafish) | Mortality/Mortality | NR-ZERO | 21 | days | 1 | μg/L | × | 16 ECOTOX | Bony,S., I. Gaillard, and A. Devaux | Genotoxicity Assessment of Two Vineyard Pesticides in Zebrafish | Int. J. Environ. Anal. Chem.90(3-6) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Growth/Wet weight (AQUIRE only) | NOEC | 60 | days post-hatch | 29 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Pimephales promelas | Growth/Length | NOEC | 60 | days post-hatch | 29 | μg/L | ○ | 16 ECOTOX | Call,D.J., L.T. Brooke, R.J. Kent, M.L. Knuth, S.H. Poirier, J.M. Huot, and A.R. Lima | Bromacil and Diuron Herbicides: Toxicity, Uptake, and Elimination in Freshwater Fish | Arch. Environ. Contam. Toxicol.16(5) | 2020/11/16 | ||||||
| 魚類 | Cyprinodon variegatus (Sheepshead minnow) | Mortality | LOEC | 32 | days | 3.6 | mg/L | ○ | 17 Aquatic OASIS (OECD QSAR Toolbox) | EFSA | Conclusion regarding the peer review of the pestic | http://dx.doi.org/10.2903/j.efsa.2005.25r | 2005 | 2023/03/14 | |||||
| 魚類 | Oncorhynchus mykiss | mortality | LC50 | 28 | days | 4.01 | mg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Danio rerio | endocrine-related endpoints | NOEC | 63 | days | >=100 | μg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Danio rerio | endocrine-related endpoint | NOEC | 35 | days | >=100 | μg/L | nominal, test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss | body length, weight, mortality | LOEC | 28 | days | 0.79 | mg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Oncorhynchus mykiss | body weight, length, condition | NOEC | 28 | days | 0.41 | mg/L | meas., test mat. | 12 ECHA Information on Registered Substances | 1 | study report | 2021/10/25 | |||||||
| 魚類 | Pimephales promelas (Fathead minnow) | LOEC | 60 | days | 61.8 | ppb | 3 USEPA Pesticide Ecotoxicity Database | A. Stavola | 1982 | 2018/02/21 |