Kretschmann Andreas, Gottardi Michele, Dalhoff Kristoffer, Cedergreen Nina
Department of Plant and Environmental Sciences, University of Copenhagen, Thorvaldsensvej 40, 1871 Frederiksberg, Denmark; Department of Analytical Biosciences, Institute for Pharmacy, University of Copenhagen, Universitetsparken 2, 2100, København Ø, Denmark.
Department of Plant and Environmental Sciences, University of Copenhagen, Thorvaldsensvej 40, 1871 Frederiksberg, Denmark.
Aquat Toxicol. 2015 May;162:94-101. doi: 10.1016/j.aquatox.2015.02.011. Epub 2015 Mar 5.
Pyrethroid insecticides are highly toxic to non-target aquatic invertebrates. Their high toxicity is synergized when co-occurring with azole fungicides in the aquatic environment. Little is known about the importance of synergy, when pyrethroids only occur during a short pulse of a few hours, as it is likely to happen in the environment, nor about the persistence of synergy over time. This study analyzed the synergistic potential of the fungicides propiconazole and prochloraz toward Daphnia magna, when exposed to a pulse (7.2 h) of α-cypermethrin at different concentrations (average pulse concentrations 0.07-11 nM). Immobilization was monitored during exposure and a subsequent recovery period (87.5h) with and without continuous co-exposure to the azoles (1.4 and 1.7 μM, respectively). EC50 values for immobilization decreased exponentially over time with a higher rate in the presence of the azoles. EC50 values for α-cypermethrin determined at the end of the experiment were 3.3±0.5 nM in the absence of azoles and 0.26±0.04, and 0.08±0.01 nM in the presence of propiconazole and prochloraz, respectively. The synergistic potential of the azoles was strongly dependent on time: no synergism could be detected during the pulse, but with azole co-exposure EC50 values decreased during the recovery period by a factor of up to 13 (propiconazole) and 61 (prochloraz) compared to values without azole exposure. Such high synergistic ratios have not been reported for pesticide mixtures in literature before. Our findings highlight that a pulse of the pyrethroid α-cypermethrin is synergized far beyond the actual pulse and beyond standardized test durations. Long post-exposure times are therefore mandatory in order to capture full synergism.
拟除虫菊酯类杀虫剂对非靶标水生无脊椎动物具有高毒性。当它们在水生环境中与唑类杀菌剂同时存在时,其高毒性会增强。对于拟除虫菊酯仅在短短几个小时的短脉冲期间出现(这在环境中很可能发生)时协同作用的重要性,以及协同作用随时间的持续性,人们了解甚少。本研究分析了杀菌剂丙环唑和咪鲜胺对大型溞的协同潜力,当大型溞暴露于不同浓度(平均脉冲浓度0.07 - 11 nM)的α - 氯氰菊酯脉冲(7.2小时)时。在暴露期间以及随后有无持续共同暴露于唑类(分别为1.4和1.7 μM)的恢复期(87.5小时)监测其固定化情况。固定化的半数有效浓度(EC50)值随时间呈指数下降,在有唑类存在时下降速率更高。在实验结束时测定的α - 氯氰菊酯的EC50值,在无唑类时为3.3±0.5 nM,在有丙环唑和咪鲜胺存在时分别为0.26±0.04和0.08±0.01 nM。唑类的协同潜力强烈依赖于时间:在脉冲期间未检测到协同作用,但在恢复期,与无唑类暴露相比,共同暴露于唑类时EC50值下降了高达13倍(丙环唑)和61倍(咪鲜胺)。此前文献中尚未报道过农药混合物有如此高的协同比。我们的研究结果突出表明,拟除虫菊酯α - 氯氰菊酯的一个脉冲所产生的协同作用远远超出实际脉冲以及标准化测试持续时间。因此,为了捕捉到充分的协同作用,长时间的暴露后时间是必不可少的。
