Department of Pesticide Science, College of Plant Protection, Nanjing Agricultural University, State & Local Joint Engineering Research Center of Green Pesticide Invention and Application, Nanjing, 210095, China.
Department of Chemistry, College of Sciences, Nanjing Agricultural University, Nanjing, 210095, China.
Environ Res. 2021 Mar;194:110696. doi: 10.1016/j.envres.2020.110696. Epub 2020 Dec 30.
The stereoselective fates of chiral pesticides in the environment has been reported in many studies. However, there is little data focused on the fate of chiral fosthiazate in the soil and aquatic ecosystems at chiral view. This study investigated the stereoselective fate of fosthiazate in the soil and aquatic ecosystems using ultra-performance liquid chromatography tandem mass spectrometry (UPLC-MS/MS) and liquid chromatography tandem time-of-flight mass spectrometry (LC-TOF/MS/MS). Significant stereoselective degradation among four fosthiazate stereoisomers were found in both greenhouse soil and water-sediment microcosms. In greenhouse soil, (1R,3S)-fosthiazate degraded faster than other three stereoisomers with the half-life of 2.7 d. The fosthiazate stereisomers in the seawater-sediment microcosm degraded more rapidly than in the river water-sediment microcosm. However, (1S,3R)-fosthiazate and (1S,3S)-fosthiazate possessed shorter degradation half-lives than their enantiomers in both microcosms, with the half-lives ranging from 3.4 d to 15.8 d. Ten degradation products were identified in the water-sediment microcosms, and, six of them were reported for the first time. Oxidation and hydrolysis were confirmed as the main degradation pathways of fosthiazate in the water-sediment microcosms. Our results revealed that the (1R,3S)-fosthiazate and (1R,3R)-fosthiazate may cause more serious ecotoxicity due to the longer half-lives than the other two stereoisomers in environment.
在许多研究中都报道了环境中手性农药的立体选择性命运。然而,从手性角度来看,关于手性福噻嗪在土壤和水生生态系统中命运的数据很少。本研究使用超高效液相色谱串联质谱(UPLC-MS/MS)和液相色谱串联飞行时间质谱(LC-TOF/MS/MS)研究了福噻嗪在土壤和水生生态系统中的立体选择性命运。在温室土壤和水-沉积物微宇宙中,发现了四个福噻嗪对映体之间存在显著的立体选择性降解。在温室土壤中,(1R,3S)-福噻嗪比其他三种对映体降解更快,半衰期为 2.7 d。海-沉积物微宇宙中的福噻嗪对映体比河-沉积物微宇宙中的降解速度更快。然而,(1S,3R)-福噻嗪和(1S,3S)-福噻嗪在两个微宇宙中的半衰期都比其对映体短,半衰期范围为 3.4 d 至 15.8 d。在水-沉积物微宇宙中鉴定出 10 种降解产物,其中 6 种是首次报道。氧化和水解被确认为福噻嗪在水-沉积物微宇宙中的主要降解途径。我们的结果表明,由于(1R,3S)-福噻嗪和(1R,3R)-福噻嗪的半衰期比其他两种对映体长,因此在环境中可能会引起更严重的生态毒性。
