紫外线和次氯酸钠对Escherichia coli和Poliovirus的消毒作用

本研究选用大肠杆菌(Escherichia coli)和脊髓灰质炎病毒(poliovirus)分别作为典型的细菌和病毒,利用培养和定量PCR的检测技术,对比研究紫外线消毒和次氯酸钠消毒对细菌和病毒的作用特点.结果表明:脊髓灰质炎病毒比大肠杆菌更难被灭活,达到1-log所需的氯剂量分别为19.2 mg·L~(-1)·min和10.14 mg·L~(-1)·min;所需的紫外线剂量分别为6.37 m J·cm~(-2)和1.81 m J·cm~(-2).定量PCR方法检测大肠杆菌和脊髓灰质炎病毒达到1-log的核酸损伤所需的紫外线剂量和氯剂量要比培养法高出1~2数量级,紫外线消毒对脊髓灰质炎病毒的RNA损伤量明显大于对大肠杆菌的DNA损伤,病毒的单链RNA对紫外线的敏感性更强,该结果与培养法正好相反.达到1-log核酸损伤脊髓灰质炎病毒所需的紫外线剂量为135 m J·cm~(-2),大肠杆菌所需的剂量为270.3 m J·cm~(-2),核酸损伤需要更多的消毒剂量,可能由于消毒过程微生物进入活性但处于非可培养状态(VBNC),以及灭活对微生物其他分子的损伤和微生物死后核酸的持续性.     

基于PMA-定量PCR选择性检测技术的病原菌消毒特性研究

建立了一种核酸染料propidium monoazide(PMA)与定量PCR技术联合选择性检测活性病原菌的技术(PMA-qPCR),以大肠杆菌作为模式菌,研究了氯和一氯胺消毒对病原菌的灭活特性.结果表明,PMA染料能够分别去除99.94%和99.99%的来自非活性大肠杆菌和沙门氏菌的DNA,PMA-qPCR技术能够有效区分活性菌与非活性菌;PMA-qPCR技术得到的氯和一氯胺消毒对大肠杆菌的灭活曲线符合一级动力学方程,灭活速率常数分别为 2.24 L·(mg·min)^-1和0.0175 L·(mg·min)^-1,低于平板培养法得到的灭活速率常数;当大肠杆菌的去除率达到99%时,采用PMA-qPCR技术检测需要的ct值相比于平板培养法从0.6 mg·L^-1·min上升到0.9 mg·L^-1·min(氯消毒)和从20 mg·L^-1·min上升到超过100 mg·L^-1·min(一氯胺消毒);随着ct值的升高,常规qPCR的检测结果基本不变,因此常规qPCR不能够反映氯和一氯胺消毒对病原菌的灭活效果.作为一种新的表征消毒特性的检测技术,PMA-qPCR技术有助于更为准确地评价氯和一氯胺消毒对病原菌的灭活效果.     

Monitoring of pathogenic microorganisms contamination during heat drying process of sewage sludge

The sewage sludge from wastewater treatment plant is a potential source of infectious organism. The number and type of pathogens in sludge depends on various factors namely, the wastewater source, the type of treatment plant, and other environmental factors such as the biological medium offered by the sewage sludge. The principal sludge-borne diseases are presented followed by discussion on biological aspect of growth and occurrence. The overall objective of this work is to estimate kinetic reduction of pathogen population in sludge during different thermal-drying process including: the agitated conductive drying, drum drying, solar drying, and fry-drying. The temperature curves were reported from literature except frying data which were determined in experiment. In order to apply the temperature influence on pathogens population, kinetic parameters for the thermal inactivation (D, z-values) were chosen from literature. Values of concentrations of each pathogen were also extracted from scientific review of pathogens in bio-solids. This study conducted to resolve the survival kinetic of Hepatitis A viruses. The result showed that a concentration of 7 × 10⁴ cfu/100 ml initially present in the sewage sludge is significantly reduced during the heat drying processes except the solar plant. The sewage sludge is completely disinfected when heated for 20 min, 10 min, and 10 s, respectively, during the agitated conductive process, vacuum fry-drying, and drum drying process.     

石灰投加与搅拌对生态厕所的灭菌效果

以发展中国家农村地区的卫生条件改善为目的,开展了简易生态厕所的粪便堆肥处理实验。在投加石灰作为抑菌剂的条件下,研究了搅拌混合对杀灭致病微生物的影响,以及使堆肥终产物达到可接受风险值所需的最佳搅拌条件。实验确定了石灰的投加量,并应用Beta-Possion模型对堆肥处置过程中致病微生物对暴露人群的健康风险进行评价,从而从健康风险控制的角度确定了最佳的搅拌次数。研究结果表明,石灰投加量约占堆肥干重1.5%,手动搅拌50次,经搅拌后放置12 h能达到可接受的风险值(3.2×10-5)。     

Bacteria inactivation by sulfate radical: progress and non-negligible disinfection by-products

● Status of inactivation of pathogenic microorganisms by SO₄^•− is reviewed. ● Mechanism of SO₄^•− disinfection is outlined. ● Possible generation of DBPs during disinfection using SO₄^•− is discussed. ● Possible problems and challenges of using SO₄^•− for disinfection are presented. Sulfate radicals have been increasingly used for the pathogen inactivation due to their strong redox ability and high selectivity for electron-rich species in the last decade. The application of sulfate radicals in water disinfection has become a very promising technology. However, there is currently a lack of reviews of sulfate radicals inactivated pathogenic microorganisms. At the same time, less attention has been paid to disinfection by-products produced by the use of sulfate radicals to inactivate microorganisms. This paper begins with a brief overview of sulfate radicals’ properties. Then, the progress in water disinfection by sulfate radicals is summarized. The mechanism and inactivation kinetics of inactivating microorganisms are briefly described. After that, the disinfection by-products produced by reactions of sulfate radicals with chlorine, bromine, iodide ions and organic halogens in water are also discussed. In response to these possible challenges, this article concludes with some specific solutions and future research directions.     

二氧化氯对剑水蚤类浮游动物的灭活与去除

进行了氯气和二氧化氯灭活剑水蚤的对比试验,并分析了pH值、有机物含量等对二氧化氯灭活剑水蚤的影响.在此基础上,对预氧化与混凝过程的协同除蚤效能进行了考察.结果表明,与氯气相比二氧化氯对剑水蚤具有更显著的灭活作用,在较低的投加量（1.0 mg/L）下,接触30 min就可以达到100％的灭活率.当水体pH值为5.7～8.0,灭活效果不受影响,但pH值为9.8可以导致灭活率降低10%.有机物含量对灭活率产生显著影响,有机物含量增加,则灭活率降低.混凝烧杯试验表明,二氧化氯投加量为0.9 mg/L时,二氧化氯预氧化与混凝沉淀的协同作用将完全去除原水中的剑水蚤.     

蛋白酶对水环境中病毒的灭活作用

以大肠杆菌噬菌体T₄作为模式病毒,研究了蛋白酶对病毒的灭活作用.试验结果表明:蛋白酶灭活病毒的效果明显. 适宜条件下,67.5u/mL的蛋白酶K处理1h对纯水中病毒(6.2×10⁵PFU/L)和生活污水中病毒(7.2×10⁵PFU/L)灭活率分别达到了99.4%和49.4%,处理3h的灭活率分别是>99.9%和81.1%;工业蛋白酶1398在75.0u/mL酶浓度下处理1h对纯水水中病毒(1.7×10⁵ PFU/L)灭活率达到74.4%.pH和温度对病毒灭活效果的影响不明显.     

次氯酸钠对剑水蚤灭活动力学及紫外强化灭活

水源水体富营养化导致剑水蚤孳生,进入供水系统后威胁供水安全.为高效控制剑水蚤污染风险,通过适当增加NaClO灭活CT值（NaClO浓度与接触时间乘积）范围,系统研究了NaClO对剑水蚤灭活动力学过程,同时探讨了紫外照射对灭活效果的强化作用.结果表明：NaClO对剑水蚤的灭活动力学过程符合迟滞型两阶段准一级动力学过程,灭活反应活化能为3774J/mol;pH值对灭活动力学过程的影响,主要通过改变溶液中HOCl和ClO^-物质的量及其化学稳定性来实现.当灭活CT值超出70mg min/L时,中性条件下NaClO对剑水蚤的灭活效率最高,碱性次之,酸性最差;浊度物质会削弱NaClO对剑水蚤的灭活效果,浊度物质会迟滞NaClO从液相主体向剑水蚤体表边界层的传质过程,被剑水蚤体表吸附后也会阻碍NaClO向剑水蚤体内的渗透过程.紫外照射尽管无法实现对剑水蚤的灭活,但可以强化NaClO对剑水蚤的灭活效果,经紫外照射后,剑水蚤灭活迟滞期消失或缩短,同时灭活反应速率常数增加.当pH值为6、7和8时,紫外照射预处理后,各自灭活反应速率常数分别由0.0093、0.02185和0.0206提高至0.0105、0.02673和0.0286.     

三角孔多孔板水力空化杀灭原水中病原微生物

利用自主研发的新型三角孔多孔板水力空化装置对胜利河原水进行消毒处理,采用压力数据采集系统采集水力空化工作段压力、显微镜观察菌体形态变化、平板计数法计数菌落总数、酶底物法检测总大肠菌群和大肠埃希氏菌;研究了三角孔多孔板的水流空化数、孔口大小、孔口数量、孔口排列和原水浓度梯度对水力空化杀灭原水中病原微生物的影响.结果表明：选择适当的原水浓度、增大孔口数量、减小孔口大小以及改进孔口排列方式（如交错式）时,均可进一步提高原水中病原微生物杀灭率.菌群杀灭率在5min时可达到稳定高效杀灭值,15min时菌落总数杀灭率可达80%以上,总大肠菌群和大肠埃希氏菌杀灭率均可达90%以上,甚至完全杀灭.     

纳米TiO2-光催化灭活水中噬菌体MS2

提出了一种简易的水中病毒灭活方法,以噬菌体MS2为模式病毒,探讨了紫外光照射时间、TiO2浓度、紫外光强度对自来水中MS2灭活效率的影响;评价了太阳光代替紫外光用于光催化灭活病毒的可行性.研究结果表明,聚乙烯(PE)材质的样品袋能更好地透过紫外光;紫外光照射6h,50mg/L的TiO2可以灭活自来水中7.95Log的MS2;紫外光强度在45μW/m2以下时,灭活率随强度的提高而增加;在溪水中,50mg/L的TiO2仅有4.87Log的灭活效率. 在太阳光下,50mg/L的TiO2在自来水和溪水中对MS2的灭活效率差异不明显,都达到了6.1Log以上,表明太阳光-TiO2灭活水中的病毒可行且高效.