Copper toxicity and chemistry in the environment: a review
about
Ocean acidification increases copper toxicity differentially in two key marine invertebrates with distinct acid-base responses.A new TK model approach to assess the effect of migration on copper toxicokinetics in inbred populations of the flour beetle, Tribolium castaneum.Metal contamination in harbours impacts life-history traits and metallothionein levels in snails.Interactions between accumulated copper, bacterial community structure and histamine levels in crayfish meat during storage.Micronized Copper Wood Preservatives: Efficacy of Ion, Nano, and Bulk Copper against the Brown Rot Fungus Rhodonia placenta.Heavy metal accumulation in Diplodus annularis, Liza aurata, and Solea vulgaris relevant to their concentration in water and sediment from the southwestern Mediterranean (coast of Sfax).Soil quality is key for planning and managing urban allotments intended for the sustainable production of home-consumption vegetables.Species-dependent variation in sensitivity of Microcystis species to copper sulfate: implication in algal toxicity of copper and controls of bloomsEcofriendly control of potato late blight causative agent and the potential role of lactic acid bacteria: a review.A review on cylindrospermopsin: the global occurrence, detection, toxicity and degradation of a potent cyanotoxin.The degradation behaviour of nine diverse contaminants in urban surface water and wastewater prior to water treatment.Heavy metal accumulation and ecosystem engineering by two common mine site-nesting ant species: implications for pollution-level assessment and bioremediation of coal mine soil.Which Metals are Green for Catalysis? Comparison of the Toxicities of Ni, Cu, Fe, Pd, Pt, Rh, and Au Salts.Influence of PNIPAm on log K(f) of a copolymerized 2,2'-bipyridine: revised bifunctional ligand design for ratiometric metal-ion sensing.Synergistic cytotoxic effects of ions released by zinc-aluminum bronze and the metallic salts on osteoblastic cells.Redox biology response in germinating Phaseolus vulgaris seeds exposed to copper: Evidence for differential redox buffering in seedlings and cotyledon.Cloning and characterization of the HSP90 beta gene from Tanichthys albonubes Lin (Cyprinidae): effect of copper and cadmium exposure.Counter-current acid leaching process for copper azole treated wood waste.High-resolution two-dimensional electrophoresis separation of proteins from metal-stressed rice (Oryza sativa L.) leaves: drastic reductions/fragmentation of ribulose-1,5-bisphosphate carboxylase/oxygenase and induction of stress-related proteins.Sorption of copper(II) and silver(I) by four bacterial exopolysaccharides.Effects of micronized and nano-copper azole on marine benthic communities.Oxidative damage induced by copper in mouse primary hepatocytes by single-cell analysis.Effects of Cutrine-Plus® algaecide and predators on wood frog (Lithobates sylvaticus) tadpole survival and growth.Copper use and accumulation in catfish culture in the Mekong Delta, Vietnam.Cesium Lead Halide Perovskite Quantum Dots as a Photoluminescence Probe for Metal Ions.Recent advances in nanomaterials for water protection and monitoring.The ribosomal protein L19 mRNA is induced by copper exposure in the swordtail fish, Xiphophorus helleri.Effect of starving and feeding on some haematological and physiological responses of the Nile catfish, Clarias gariepinus exposed to copper at extreme seasons.The Effects of Acute Copper and Ammonia Challenges on Ammonia and Urea Excretion by the Blue Crab Callinectes sapidus.Copper transport and compartmentation in grape cells.Copper content of grape and wine from Italian farms.Evaluation of new Cu(II) complexes as a novel class of inhibitors against plant carbonic anhydrase, glutathione reductase, and photosynthetic activity in photosystem II.Copper speciation and isotopic fractionation in plants: uptake and translocation mechanisms.Nanosized titanium dioxide influences copper-induced toxicity during aging as a function of environmental conditions.The importance of experimental time when assessing the effect of temperature on toxicity in poikilotherms.Complexation as the most important factor in the fate and transport of heavy metals in the Dnieper water bodies.Synchrotron-based chemical imaging reveals plumage patterns in a 150 million year old early birdErratum to “Novel Facial Conducting Polyamide-Based Dithiophenylidene Cyclyhexanone Moiety Utilized for Selective Cu2+ Sensing”Novel Facial Conducting Polyamide-Based Dithiophenylidene Cyclyhexanone Moiety Utilized for Selective Cu2+ SensingInorganic fungicides as routinely applied in organic and conventional agriculture can increase palatability but reduce microbial decomposition of leaf litter
P2860
Q31048091-8EC26F7C-2FC3-4412-ADA4-2552E89C64CEQ33843545-BACF01A9-1638-458F-B4D8-28B6DC0D6B3BQ33865842-E4235442-B67E-4DC9-83CB-ACE96AA36B71Q35059895-0459FCBB-B177-43D8-A5A4-9277B1CB37EEQ35837053-5C47EA4B-BB78-4411-9E32-AC9E959FC228Q35978449-3AB037EE-F3F6-46D9-9754-32527B20281DQ36035650-911FDB5F-5183-4B4C-BDDE-6A1455FBE7B3Q37581512-C4B9FB2C-7407-4194-AF6B-35413FE4C373Q38032191-43658A92-9923-4ED3-A75A-E72E944312B0Q38140644-092DDC11-48EB-40C6-B882-04AEFC04A20DQ38385248-411FC0F2-4D79-4A13-B234-C2BC1F6F2014Q38867731-9F8B933E-97E4-4180-BB35-40469D363762Q38929495-FA39D254-2D6D-4993-94EF-C7DBD0C231B0Q38997677-F6FBB072-4D0F-4208-8176-095B22A0C5C1Q39164270-77B46C30-C328-4AAD-A086-0F5C504D4D4CQ42370680-DC11EFA9-ACB5-4682-94F5-C112C3693D24Q42616253-17F58E44-1596-488C-88E1-9E16CA6D4C19Q43352790-EBD2C8C0-B265-4755-AC42-57AAADE7A21AQ43729879-5A55C3F0-D49E-4776-942A-B29754B31E06Q45055390-CD731CC1-D4C3-4AFC-8A7F-DA98007829CFQ46274254-7C7A0563-334C-483C-98FA-A3D07E1CBB41Q46671527-A43D033E-A320-4F36-977A-48EAA3BE2355Q46877253-EC3F08EC-FF78-4D31-9276-8FC0D8EBC943Q46977171-E7C1B231-49DD-48AD-A525-3AA2E95408D6Q47825861-C34E32E2-8795-4D45-8C39-B5F588709D0CQ47865017-CC42F82B-8802-4F3B-B9EA-4324E1F0F333Q48055530-EFB0FF50-FDC2-49DF-95FE-CA31490A7A40Q48136691-E479901D-7E5C-4036-95A3-991E4B87D4E9Q50184316-82A933E1-7123-4FBE-B2C6-538146D45E07Q50491160-20779C88-0F2E-4AA5-A319-07BB5E557E35Q50740699-D65C1973-9C35-4758-B38E-EEDB779C79EDQ50878593-797E7B9F-EF48-48AF-B31F-3D104A09A530Q51060759-CB9D1161-0E41-4DED-8629-3A424E2AAB71Q51319763-463CC885-A6F2-449F-BE4D-3420AAA044B0Q51459390-4D9B1AB7-7271-4AF4-8614-678649C12F19Q53722934-FE2A22CA-A620-4557-BE6D-514F2EF009DAQ56038838-1DBF9280-394E-40AC-9F0A-ADE53EC9A341Q56994575-F24B8451-ADB4-4796-83F8-EECD4E38C9FAQ56994650-72C04736-A6CE-4136-B32D-0CE21C29ED8CQ57005297-EB502A82-553F-44A0-B6C9-5927CB3BE5F8
P2860
Copper toxicity and chemistry in the environment: a review
description
article
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в березні 1989
@uk
ലേഖനം
@ml
name
Copper toxicity and chemistry in the environment: a review
@en
Copper toxicity and chemistry in the environment: a review
@nl
type
label
Copper toxicity and chemistry in the environment: a review
@en
Copper toxicity and chemistry in the environment: a review
@nl
prefLabel
Copper toxicity and chemistry in the environment: a review
@en
Copper toxicity and chemistry in the environment: a review
@nl
P356
P6366
P1476
Copper toxicity and chemistry in the environment: a review
@en
P2093
C. A. Flemming
J. T. Trevors
P2888
P304
P356
10.1007/BF00228784
P577
1989-03-01T00:00:00Z
P6366
2057489611