Formation and cytotoxicity of a new disinfection by-product (DBP) phenazine by chloramination of water containing diphenylamine

Disinfection by-products (DBPs) in drinking water have caused worldwide concern due to their potential carcinogenic effects. The formation of phenazine from diphenylamine (DPhA) chloramination was studied and its cytotoxicities for two human cancer cells were also investigated. Phenazine was detected synchronously with the consumption of DPhA by chloramination, which further confirmed that the new DBP phenazine can be produced along with N-nitrosodiphenylamine (NDPhA) from DPhA chloramination. The formation of phenazine had a maximum molar yield with solution pH increasing from 5.0 to 9.0, with phenazine as the main product for DPhA chloramination at lower pH, but higher pH favored the formation of NDPhA. Thus, solution pH is the key factor in controlling the formation of phenazine and NDPhA. Both the initial DPhA and chloramine concentrations did not show a significant effect on the molar yields of phenazine, although increasing the chloramine concentration could speed up the reaction rate of DPhA with chloramines. The cytotoxicity assays showed that phenazine had significant cell-specific toxicity towards T24 (bladder cancer cell lines) and HepG2 (hepatic tumor cell lines) cells with IC50 values of 0.50 and 2.04 mmol/L, respectively, and T24 cells being more sensitive to phenazine than HepG2 cells. The IC50 values of phenazine, DPhA, and NDPhA for T24 cells were of the same order of magnitude and the cytotoxicity of phenazine for T24 cells was slightly lower than that of NDPhA (IC50, 0.16 mmol/L), suggesting that phenazine in drinking water may have an adverse effect on human health.     

水中痕量亚当氏剂和二苯胺的固相微萃取方法研究

研究了固相微萃取(SPME)-高效液相色谱(HPLC)测定水样中痕量亚当氏剂和二苯胺的分析方法.对SPME的条件如萃取纤维、萃取时间、萃取温度、离子强度、解吸方式、解吸溶剂、解吸时间进行了优化,并用于地下水等实际水样的分析.SPME优化的条件为:选用60μmPDMS/DVB萃取纤维在室温25℃下直接萃取60min,磁力搅拌速度为1100r.min-1,然后萃取纤维在解吸室内静态解吸9min后进行HPLC分析.液相色谱分离条件为ZORBAXSBC18柱(4.6mmi.d.×250mm,5.0μm),流动相为甲醇-水(70:30,V/V),流速为1.0ml.min-1,二极管阵列检测器波长为280nm.方法线性范围为0.005mg.l-1—0.5mg.l-1(R>0.99),两种物质的检出限(S/N=3)分别为0.003mg.l-1和0.002mg.l-1.加标回收率分别在89.6%—100.4%和97.5%—100.1%(n=5)之间,相对平均标准偏差(RSD)分别在4.5%—6.2%和3.8%—6.7%之间.该方法快速、简便,无需使用有机溶剂,适于水样中痕量物质的分析.     

用废炭黑吸附处理二苯胺生产废水

利用制氢生产中产生的废炭黑作吸附剂,对二苯胺生产废水中的苯胺进行吸附,找出了较佳吸附条件和脱附方法,试验表明,用废炭黑吸附处理二苯胺生产废水具有吸附速度快,吸附效果好,处理费用等优点。