Joint algal toxicity of 16 dissimilarly acting chemicals is predictable by the concept of independent action.
about
Concentration addition, independent action and generalized concentration addition models for mixture effect prediction of sex hormone synthesis in vitroExtended biotic ligand model for prediction of mixture toxicity of Cd and Pb using single metal toxicity data.Using legacy data to relate biological condition to cumulative aquatic toxicity in the Willamette River Basin (Oregon, USA).Risk of herbicide mixtures as a key parameter to explain phytoplankton fluctuation in a great lake: the case of Lake Geneva, Switzerland.Exposure to common quaternary ammonium disinfectants decreases fertility in miceA docking-based receptor library of antibiotics and its novel application in predicting chronic mixture toxicity for environmental risk assessment.Dose-response analysis in the joint action of two effectors. A new approach to simulation, identification and modelling of some basic interactionsEnvironmental risk assessment of pesticides in the River Madre de Dios, Costa Rica using PERPEST, SSD, and msPAF models.Low-level exposure to multiple chemicals: reason for human health concerns?A concentration addition model to assess activation of the pregnane X receptor (PXR) by pesticide mixtures found in the French diet.Dispelling urban myths about default uncertainty factors in chemical risk assessment--sufficient protection against mixture effects?Quantitative Characterization of the Toxicities of Cd-Ni and Cd-Cr Binary Mixtures Using Combination Index Method.Genotoxic mixtures and dissimilar action: concepts for prediction and assessmentMechanisms of Action of Compounds That Enhance Storage Lipid Accumulation in Daphnia magna.Two-stage prediction of the effects of imidazolium and pyridinium ionic liquid mixtures on luciferase.A toxicokinetic study of specifically acting and reactive organic chemicals for the prediction of internal effect concentrations in Scenedesmus vacuolatus.Chronic and acute risk assessment of human exposed to novaluron-bifenthrin mixture in cabbage.In vitro hepatotoxicity of 'Legal X': the combination of 1-benzylpiperazine (BZP) and 1-(m-trifluoromethylphenyl)piperazine (TFMPP) triggers oxidative stress, mitochondrial impairment and apoptosis.The Comparison of the Combined Toxicity between Gram-negative and Gram-positive Bacteria: a Case Study of Antibiotics and Quorum-sensing Inhibitors.Toxic Assessment of Triclosan and Triclocarban on Artemia salina.Ecotoxicological evaluation of propranolol hydrochloride and losartan potassium to Lemna minor L. (1753) individually and in binary mixtures.Independent action between DvSnf7 RNA and Cry3Bb1 protein in southern corn rootworm, Diabrotica undecimpunctata howardi and Colorado potato beetle, Leptinotarsa decemlineata.Seven benzimidazole pesticides combined at sub-threshold levels induce micronuclei in vitro.Additivity and Interactions in Ecotoxicity of Pollutant Mixtures: Some Patterns, Conclusions, and Open Questions.Sustainable risk management of emerging contaminants in municipal wastewaters.Drinking water treatment is not associated with an observed increase in neural tube defects in mice.Realistic environmental mixtures of micropollutants in surface, drinking, and recycled water: herbicides dominate the mixture toxicity toward algae.Critical issues in using the common mixture toxicity models concentration addition or response addition on species sensitivity distributions: a theoretical approach.Joint action and lethal levels of toluene, ethylbenzene, and xylene on midge (Chironomus plumosus) larvae.Toxicity evaluation of two typical surfactants to Dunaliella bardawil, an environmentally tolerant alga.Toxicity of cadmium, anthracene, and their mixture to Desmodesmus subspicatus estimated by algal growth-inhibition ISO standard test.Development of QSAR-based two-stage prediction model for estimating mixture toxicity.A mixture of seven antiandrogens induces reproductive malformations in rats.Unexpected toxic interactions in the freshwater amphipod Gammarus pulex (L.) exposed to binary copper and nickel mixtures.Toxicity of binary mixtures of enantiomers in chiral organophosphorus insecticides: the significance of joint effects between enantiomers.Predicting herbicide mixture effects on multiple algal species using mixture toxicity models.Reproductive toxicity of binary and ternary mixture combinations of nickel, zinc, and lead to Ceriodaphnia dubia is best predicted with the independent action model.The use of growth and behavioral endpoints to assess the effects of pesticide mixtures upon aquatic organisms.The combined toxicity assessment of carp (Cyprinus carpio) acetylcholinesterase activity by binary mixtures of chlorpyrifos and four other insecticides.Scientific Opinion on the relevance of dissimilar mode of action and its appropriate application for cumulative risk assessment of pesticides residues in food
P2860
Q28535588-E91A36B5-5356-49D5-A68B-3C3DC9F867FBQ33888342-E8C0082E-F064-40A2-A3D4-528324D42AD9Q34040152-EDF198B1-F984-4315-B3DC-0C2FD1A0DAB7Q34372017-A665D21D-149B-4ECF-A575-DE3C0F7E2ECBQ34452454-FA06F672-26EF-4646-A4FE-00C655FB466FQ34473515-61138B72-7DF4-4F00-AF9E-DEF95952E0F1Q34700267-963D82BA-7B4E-4643-A3E1-49CE6F12EEE4Q36129717-5E3C3ABB-C1AD-4D9C-BBBD-48CF502C59ACQ36326664-D7D7717D-0CD3-4FF6-95A9-5717619EFE8CQ36801931-550DD5F8-348C-4DA4-A62A-E34AE97CBC9AQ37004073-CA6E154B-F51E-49BD-B78B-304D1C8B5E6DQ37504253-635DA5F3-54F7-454D-9FB7-C3E067FF562CQ37589544-E661E526-E7AE-43E6-B6FD-135EF9A456BEQ37661216-6B32F6FE-6A9D-426A-8332-D1657DA17ECBQ39019460-3446BD5A-B9C0-472A-BD0F-ABEFDBF05087Q39121971-EB8CCA31-314A-44BE-AEE1-05F42C36ACCEQ39464874-C9E67D9F-2D6F-4083-8EDA-976727AE4706Q39643944-329EC6EA-4F06-4510-B44E-F3D9BDD6971FQ40588260-C36A5B8F-4492-4AE6-871F-3142B98D89A8Q40604763-9D4ECF8A-FE33-4CC1-8E7D-08ABC6F2D233Q41109766-AB0C5AF6-D926-4C13-866D-06622ADB7923Q41313245-D6391977-F25C-430B-A80B-58C346BD2BFDQ42153594-93D77974-B132-4274-ADC7-05E70D28E1CBQ42361379-35019A45-F008-49E6-B836-1037F16B6D72Q43309404-313CBD17-2304-41D1-9973-1620000C37AEQ43312434-C06D44C9-0CD7-4FA5-8A1D-9C6495D38462Q43314733-51F4CDB4-F3F8-4ABF-BA18-C6EA88460FC4Q44063732-FD13A2E7-84AF-48E4-9D63-615D1F04FE54Q44197390-C376F827-18FF-4B48-93A3-E109DF1AC4A0Q44375595-58841315-91BF-48C3-91FE-F43ED979BFF8Q44377848-72CA352C-EF2B-4DD2-BD9B-4770AA89BED5Q44702589-54162982-DE9F-4EF8-AC55-6EAF748EBCE1Q44872672-B93DCAC9-1D8A-4094-AC59-11591D8725B9Q45971367-4FAB5264-74F6-4ADA-9BA1-B5834E2DA935Q46078724-127DFD20-3CB2-4E97-930C-3138EE5A89F6Q46402148-21692732-9F3F-4866-A646-F9DE9DE8D7FDQ46626583-7AFE29B5-DA45-42D3-927E-AE8C0B0BBC87Q46928747-0FADF038-8B24-458B-BF55-A0212830E84FQ46956228-7FAC6254-C7ED-4B08-A766-8CCF663551C1Q47154000-E7DE523C-D415-48A3-B7C3-80DF0A97E805
P2860
Joint algal toxicity of 16 dissimilarly acting chemicals is predictable by the concept of independent action.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年学术文章
@wuu
2003年学术文章
@zh
2003年学术文章
@zh-cn
2003年学术文章
@zh-hans
2003年学术文章
@zh-my
2003年学术文章
@zh-sg
2003年學術文章
@yue
2003年學術文章
@zh-hant
name
Joint algal toxicity of 16 dis ...... concept of independent action.
@en
Joint algal toxicity of 16 dis ...... concept of independent action.
@nl
type
label
Joint algal toxicity of 16 dis ...... concept of independent action.
@en
Joint algal toxicity of 16 dis ...... concept of independent action.
@nl
prefLabel
Joint algal toxicity of 16 dis ...... concept of independent action.
@en
Joint algal toxicity of 16 dis ...... concept of independent action.
@nl
P2093
P1433
P1476
Joint algal toxicity of 16 dis ...... concept of independent action.
@en
P2093
Altenburger R
Boedeker W
P356
10.1016/S0166-445X(02)00133-9
P577
2003-03-01T00:00:00Z