Key Laboratory of Pollution Processes and Environmental Criteria, Ministry of Education, Tianjin Key Laboratory of Environmental Remediation and Pollution Control, College of Environmental Science and Engineering, Nankai University, Tianjin 300071, China.
Department of Analytical Chemistry, The Connecticut Agricultural Experiment Station, New Haven, CT 06504, United States.
Sci Total Environ. 2019 Feb 15;651(Pt 1):1154-1165. doi: 10.1016/j.scitotenv.2018.09.229. Epub 2018 Sep 19.
The accumulation and metabolism of 2, 2', 4, 4', 5, 5'-hexabrominated diphenyl ether (BDE-153) in Amaranthus mangostanus L. (amaranth) as affected by different concentrations of biochar (1.3 to 26.6 g/L) under hydroponic conditions exposed to 10 μg/L BDE-153 after 10 days were investigated. Biochar significantly reduced BDE-153 shoot and root content by 27.5-61.6% and 73-95.3%, respectively. In general, BDE-153 migration from solution to amaranth decreased with increasing the doses of biochar. BDE-153 metabolites altered with doses of biochar. The ratio of de-BDEs to BDE-153 in root was polynomial correlated to biochar dose (R = 0.9356**). Root and shoot Fe content was positively correlated with the BDE-153 amounts (R = 0.948** and 0.822*, respectively). Though the higher biochar dose could obviously control BDE-153 uptake by the vegetable, the toxicity was caused more significantly. For instances, the high concentration of biochar at 26.6 g/L reduced pigment content, increased total ROS, and elevated antioxidant enzyme activity. At the same time, the O intensity was linearly positively correlated with de-BDEs in root (R = 0.7324*) while photosynthetic parameter F/fm intensity was polynomial correlated to BDEs in shoot (R = 0.9366*). Transmission electron microscopy (TEM) confirmed that exposure to BDE-153 and high concentration biochar at 26.6 g/L severely altered the chloroplasts in terms of the organelle shape and the presence of starch granules in the chloroplast. Taken together, biochar as a soil amendment could significantly control BDE-153 uptake and enhance BDE-153 metabolism in vegetables, but considering the dose of biochar to avoid its toxicity with higher dose.
在水培条件下,研究了不同浓度生物炭(1.3 至 26.6 g/L)对受 10μg/L BDE-153 暴露 10 天后满江红(苋菜)中 2,2',4,4',5,5'-六溴二苯醚(BDE-153)积累和代谢的影响。生物炭可使 BDE-153 的地上部和根部含量分别降低 27.5-61.6%和 73-95.3%。通常,随着生物炭剂量的增加,BDE-153 从溶液向苋菜的迁移减少。BDE-153 代谢物随生物炭剂量而变化。根中脱溴 BDEs 与 BDE-153 的比值与生物炭剂量呈多项式相关(R = 0.9356**)。根和地上部铁含量与 BDE-153 含量呈正相关(R = 0.948和 0.822)。尽管较高的生物炭剂量可以明显控制蔬菜对 BDE-153 的吸收,但毒性更为明显。例如,26.6 g/L 高浓度生物炭会降低色素含量,增加总 ROS,并提高抗氧化酶活性。同时,O 强度与根中脱溴 BDEs 呈线性正相关(R = 0.7324),而光合参数 F/fm 强度与地上部 BDEs 呈多项式相关(R = 0.9366*)。透射电子显微镜(TEM)证实,暴露于 BDE-153 和 26.6 g/L 高浓度生物炭会严重改变叶绿体的形状和叶绿体中淀粉颗粒的存在。总之,生物炭作为土壤改良剂可以显著控制 BDE-153 的吸收并增强蔬菜中 BDE-153 的代谢,但需考虑生物炭的剂量,以避免高剂量带来的毒性。
