Water treatment plants faced with toxic cyanobacteria have to be able to remove cyanotoxins from raw water. In this study we investigated the efficacy of ozonation coupled with various filtration steps under different cyanobacterial bloom conditions. Cyanobacteria were ozonated in a laboratory-scale batch reactor modeled on a system used by a modern waterworks, with subsequent activated carbon and sand filtration steps. The presence of cyanobacterial toxins (microcystins) was determined using the protein phosphatase inhibition assay. We found that ozone concentrations of at least 1.5 mg/L were required to provide enough oxidation potential to destroy the toxin present in 5 X 10(5 )Microcystis aeruginosa cells/mL [total organic carbon (TOC), 1.56 mg/L]. High raw water TOC was shown to reduce the efficiency of free toxin oxidation and destruction. In addition, ozonation of raw waters containing high cyanobacteria cell densities will result in cell lysis and liberation of intracellular toxins. Thus, we emphasize that only regular and simultaneous monitoring of TOC/dissolved organic carbon and cyanobacterial cell densities, in conjunction with online residual O(3) concentration determination and efficient filtration steps, can ensure the provision of safe drinking water from surface waters contaminated with toxic cyanobacterial blooms.
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机译:面对有毒蓝细菌的水处理厂必须能够从原水中去除氰毒素。在这项研究中,我们研究了在不同的蓝藻水华条件下,臭氧化的效果以及各种过滤步骤。蓝细菌在实验室规模的间歇式反应器中进行了臭氧处理,该反应器以现代水厂使用的系统为模型,随后进行了活性炭和砂子过滤步骤。使用蛋白磷酸酶抑制试验确定了蓝藻毒素(微囊藻毒素)的存在。我们发现需要至少1.5 mg / L的臭氧浓度才能提供足够的氧化潜力,以破坏5 X 10(5)铜绿微囊藻细胞/ mL [总有机碳(TOC),1.56 mg / L]中存在的毒素。高原水TOC可以降低游离毒素氧化和破坏的效率。另外,含有高蓝细菌细胞密度的原水的臭氧化将导致细胞溶解和细胞内毒素的释放。因此,我们强调只有定期和同时监测TOC /溶解的有机碳和蓝细菌的细胞密度,并结合在线残留O(3)浓度测定和有效的过滤步骤,才能确保从受水污染的地表水中提供安全的饮用水有毒的蓝藻水华。
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