发光细菌法评价排污口污水中总有机污染物毒性

利用发光细菌发光原理,建立以明亮发光杆菌(photobacterium phosphoreum)T3变种作为毒性测试物种检测环境中总有机污染物毒性的方法,并用该方法评价环渤海排污口总有机物毒性分布状况。测试结果显示,建立的相关方程及相关性显著性检验P0.01,HgCl2 EC50值基本在0.10±0.02 mg/L范围内波动,指标符合方法规定要求,即发光菌监测排污口中总有机污染物毒性测试结果是准确可信的。用发光细菌法评价环渤海20个排污口,其中剧毒占10%,高毒占25%,重毒占5%,中毒占10%,低毒占50%。发光细菌法能客观、快速、准确地反映废水中总有机污染物毒性状况,该方法在水质监测总有机物毒性中有着广泛的应用前景。     

水样发光细菌急性毒性测试的方式与表征

选取不同类型的环境和污染源水样开展了发光细菌毒性测试,针对不同环境管理目标,探讨了急性毒性定量表征方式。发光细菌急性毒性测试在环境应急监测、水源早期生物预警中,采用绘制毒性预警基线图的方式比较可行。在污染源监督监测中,对于发光抑制率低于60%、无法求出EC50的样品,采用等效毒性参照物的质量浓度表征废水的毒性;对于发光抑制率高于60%,采用稀释因子表示样品的毒性更直观可靠。     

As水质毒性发光细菌及微生物燃料电池在线监测技术的比选研究

针对实际应用需要,对比研究了发光细菌和微生物燃料电池两种不同毒性预警技术对典型类金属砷离子的响应差异,并考察了丰水期、枯水期河水水质背景干扰对响应信号的影响。结果表明,发光细菌法对砷离子响应较为灵敏,微生物燃料电池法对砷离子的响应非常灵敏。发光细菌法受水体水质背景干扰大,且不同生产厂家的仪器差异显著,推测可能是由于菌株来源不同、仪器响应灵敏度差异所造成。微生物燃料电池法对背景干扰的抗性较强,稳定性较高,河水加标与纯水加标样本的剂量-效应曲线差别不大。基于上述研究结果,分析了两种技术监测类金属砷的优缺点并提出实际在线运行的相关建议。     

发光细菌毒性法在饮用水水质评估与预警中的应用

通过对温州地区水源地、自来水等水质指标的研究,评估发光细菌(费氏弧菌)生物预警毒性监测的有效性,并结合实际案例,探讨以发光细菌生物毒性指标评估、预警水质的可行性。在正常情况下,饮用水水源地水质在低发光抑制率区间(±18%),如果水质遭遇农药污染等非正常情况,发光抑制率明显升高。在自来水净水过程中的各个处理阶段,发光细菌的水质毒性检测表现出敏感性,可以用于水质安全在线实时监控。     

典型化工污水处理厂废水及受纳水体的生物急性毒性监测方法应用研究

为了研究生物急性监测方法对监测典型化工污水处理厂废水的适用性,选择2家常州市典型的化工园区污水处理厂("常A"和"常B"),进行了发光细菌、藻类、大型溞和斑马鱼卵4种不同层次受试生物的急性毒性检测。研究表明,发光细菌急性毒性、藻类叶绿素荧光毒性在2个污水处理厂中均被检测到,发光细菌急性毒性通常进水大于出水,但在投放大量氧化消毒剂时,出水表现出剧毒。藻类叶绿素荧光毒性最高值出现在常B进水中。大型溞和斑马鱼卵急性毒性仅在常B进出水样中有检出,受纳河道下游水样虽未表现出急性毒性,但可观察到斑马鱼卵各类发育畸形。4种生物急性毒性检测方法中,发光细菌适用范围最广,藻类、大型溞和斑马鱼卵急性毒性方法可根据监测目的和工业园区特点相应选择。实验结论可为化工污水处理厂尾水排放过程中生物毒性监测的常态化提供方法选择,为管理部门制定排放标准提供依据。     

发光菌毒性试验在项目竣工环保验收监测中的应用

某敏感化工技改项目曾因超标排污引发跨地区厂群纠纷被责令停产整改,为考察该项目整改后废水处理设施的运行效果,保障水生生物安全,在该项目竣工环境保护验收监测时,采用发光细菌毒性试验检测废水的急性毒性.结果表明,达标排放的废水对生物的急性毒性为低毒,试验结果与常规验收监测结果有可比性,发光细菌毒性试验可用于必须公示的敏感项目竣工环境保护验收监测.     

发光细菌在环境监测中的应用

各种成分复杂的工业污水对环境的综合影响对生物的危害很难客观反映出来.我们利用发光细菌作为生物指示剂监测环境污染,它不仅具有快速、简便、灵敏的特点,而且能够考虑拮抗作用和协同作用,综合地反映污水的生物毒性,在几分钟内测出用其他生物监测方法在几天内才能得到的结果.     

厌氧-缺氧-好氧处理工艺的污水处理厂进出水的毒性评价

为了准确评估厌氧-缺氧-好氧（A²/O）处理工艺对废水毒性的削减效率，采用斑马鱼胚胎急性毒性实验、发光细菌急性毒性实验和小鼠L929细胞毒性实验进行测试，结合理化指标，通过毒性当量（TU）法、平均毒性（AvTx）法、毒性指数（TxPr）法、最敏感测试（MST）法和潜在生态毒性效应（PEEP）法对常州市6家污水处理厂（生活污水、综合废水、化工废水、制药废水）进水和出水的生物毒性进行了评价。结果表明，斑马鱼胚胎的毒性敏感程度最高，3种受试生物的毒性评价结果具有较好的一致性。理化达标的污水处理厂出水仍存在一定的生物毒性效应，出水毒性较大的是综合污水处理厂，排入受纳水体后可能会对周围的生态环境产生潜在的生态风险。A²/O处理工艺对各污水处理厂进水的毒性削减较好，其中对制药废水的毒性削减最高，AvTx、TxPr、MST和PEEP的毒性削减率分别为99.45%、99.64%、99.48%和69.66%。与AvTx、TxPr、MST法相比，PEEP法能够更综合地评价废水毒性。     

发光细菌法监测废水综合毒性研究

运用发光细菌法对 2 6个污染源废水样的毒性进行测定。并以毒性较为稳定的 Hg Cl2 作参比毒物 ,使此法所测得的毒性定量化。据水质毒性分级标准 ,对水样毒性的测定结果进行评价 ,属 级低毒的 1 1个 , 级中毒 4个 , 级重毒1个 , 级高毒 3个 , 级剧毒 7个。另从辽阳化纤厂五个废水样可以看出距离污染源越近毒性越强。这一结果既与实际情况相符又与鱼的毒性试验结果一致 ,证明发光菌监测工业废水是可行的。     

发光细菌法评价工业废水的毒性

用发光细菌测定法估算了两城市污水对河道水体污染的分担率，评价了工厂排放废水的毒性，并据此确定了污染源监督管理中应优先治理的工厂（车间）废水。     

京杭运河(苏州段)水质急性综合毒性研究

从2009年3月至2010年10月对京杭运河(苏州段)的4个监测断面进行了水质急性综合毒性和地表水主要理化项目的调查,结果表明:京杭运河(苏州段)水质急性综合毒性基本处在低毒水平,各断面基本呈现水质急性毒性水平枯水期>平水期>丰水期的规律,水质急性综合毒性测定结果基本与同步理化监测结果一致。     

淡水发光菌对工业废水的生物毒性研究

发光菌作为指示生物用于污染源水体的生物毒性测定具有快速、灵敏、低廉等优点,现已广泛用于环境毒物综合急性毒性测定、筛查、监测及特异毒物监测中.文章利用淡水发光菌Q67对东北地区各行业典型企业的出水口进行急性毒性试验,同时结合化学指标进行了综合评估,试验结果表明:急性毒性试验和化学指标并非在任何水体都相关,但急性毒性试验是化学试验的必要补充.     

Necessity of Toxicity Assessment in Turkish Industrial Discharges (Examples from Metal and Textile Industry Effluents)

Toxicity of some organic and inorganic chemicals to microorganisms is an important consideration in assessingtheir environmental impact against their economic benefits.Microorganisms play an important role in several environmentalprocesses, both natural and engineered. Some organic and inorganics at toxic levels have been detected in industrial discharges resulting in plant upsets and discharge permit violations. In addition to this, even though in some cases the effluent wastewater does not exceed the discharge limits,the results of toxicity tests show potential toxicity. Toxicityknowledge of effluents can benefit treatment plant operators inoptimising plant operation, setting pre-treatment standards, and protecting receiving water quality and in establishing sewer discharge permits to safeguard the plant. In the Turkish regulations only toxicity dilution factor (TDF) with fish is part of the toxicity monitoring program of permissible wastewater discharge. In various countries, laboratory studiesinvolving the use of different organisms and protocol for toxicity assessment was conducted involving a number of discharges.In this study, it was aimed to investigate the acute toxicity of textile and metal industry wastewaters by traditional and enrichment toxicity tests and emphasize the importance of toxicity tests in wastewater discharge regulations. The enrichment toxicity tests are novel applications and give anidea whether there is potential toxicity or growth limiting and stimulation conditions. Different organisms were used suchas bacteria (Floc and Coliform bacteria) algae (Chlorella sp.), fish (Lepistes sp.) and protozoan (Vorticella sp.) to represent four tropic levels. The textile industry results showed acute toxicity for at least one organism in 8 out of 23 effluent samples. Acute toxicity for at least two organisms in 7 out of 23 effluent sampling was observed for the metal industry. The toxicity test results were assessed with chemical analyses such as COD, BOD, color and heavy metals. It was observed that the toxicity of the effluents could not be explained by using physicochemical analyses in 5 cases for metal and 4 cases for the textile industries. The results clearly showed that the useof bioassay tests produce additional information about the toxicity potential of industrial discharges and effluents.     

The continuous monitoring of field water samples with a novel multi-channel two-stage mini-bioreactor system

Toxicity monitoring of field water samples was performed using a novel multi-channel two-stage mini-bioreactor system and genetically engineered bioluminescent bacteria for the continuous monitoring and classification of the toxicity present in the samples. The toxicity of various samples spiked with known endocrine disrupting chemicals and phenol was also investigated for system characterization. The field samples used in this study were obtained from two different sites on a monthly basis--from a drinking water treatment plant, referred to as site N, and from a stream near a dam which is currently being constructed, referred to as site T. These samples were either pumped or injected into the second mini-bioreactors to initiate the toxicity test. Most of the samples did not show any specific toxicity. However, one sample showed to have, based upon the detection results, and was deemed toxic. The samples spiked with phenol showed possible responses in the DPD2540 and TV1061 channels, indicating the occurrence of both membrane and protein damage due to phenol. In the tests using an endocrine disrupting chemical, bisphenol A, DNA damage was detected in the DPD2794 channel with a concentration of 2 ppm. Finally, a simple but novel early warning protocol that can be used in a drinking water reservoir and a suspected place where effluents of toxic materials enter the water sourse was suggested with a schematic diagram. In conclusion, this system showed good feasibility for use as a toxicity monitoring system in the field and as an early warning system, indicating if effluents are toxic.     

A Multi-Channel Continuous Water Toxicity Monitoring System: Its Evaluation and Application to Water Discharged from a Power Plant

A multi-channel continuous water toxicity monitoring system was, after confirming the systems' performance, implemented to samples of water discharged from power plants to detect and classify their toxicity using several recombinant bioluminescent bacteria. Each channel of the system is composed of a series of two mini-bioreactors to enable a continuous operation, i.e., without system interruption due to highly toxic samples. A different recombinant bacterial strain was present in each channel: DPD2540 (fabA::lux CDABE), DPD2794 (recA::luxCDABE), and TV1061 (grpE::luxCDABE), which are induced by cell membrane-, DNA-, and protein-damaging agents, respectively. GC2 (lac::luxCDABE) is a constitutive strain, whose bioluminescence is reduced by an increase in cellular toxicity. Phenol and mitomycin C (MMC) were used for evaluating the system's performance to detect toxic chemicals. These samples were injected into the second mini-bioreactor according to a step or bell-curve manner. The field samples used in this study were obtained from the water discharged from two different power plants in Korea – from a nuclear power plant and a thermo-electronic power plant, and were injected into the second mini-bioreactor to initiate the toxicity test. Each channel showed specific bioluminescent (BL) response profiles due to the toxic compounds present in the water samples. Comparing the BL signals between the standard toxic chemical samples and discharged water samples, the equivalent toxicity of the field water could be estimated. Finally, it was proved that this novel continuous toxicity monitoring system can be used as an alternative tool for the quick monitoring and control of water quality, as well as aid in the setting up of a new monitoring strategy to protect the source of tap water and in the prevention of polluted water discharge.     

土壤中氰化物的快速测定——以江苏镇江电镀园区土壤监测为例

以电镀园区为例,利用流动注射仪对园区土壤中的氰化物进行了快速测定,并与传统分光光度法进行了比对.结果表明：流动注射法中准确度和精密度均满足监测要求;pH为3.8、蒸馏温度为125℃是氰化物测定的最佳实验条件;流动注射法和传统方法测试的结果相对标准偏差（RSD）均小于8％.该法具有分析速度快、稳定性好等特点,适用于大批量土壤样品测定.     

A novel approach to rapid detection of acute water toxicity and its policy implications for grassroots sustainable environmental monitoring

Unknown chemicals, emerging contaminants, and the resulting reactions among them make early detection and warning of acute water toxicity extremely challenging. The conventional approach using small fish for toxicity monitoring normally requires a designated species of fish and over a week's time to complete, including dilution of the wastewater, a pre-test, and a full test. It often increases chances for error and delays emergency management. This paper reports a novel approach, based on grassroots knowledge and field and lab experience in Jilin, China. This approach uses a combination of different species of aquarium fish to achieve fast and reliable monitoring. It tests the original source water directly without going through the dilution procedure, while paying attention to the time factor. The approach does not require a pre-test and may shorten the time needed for detecting acute toxicity to a few minutes, using a new classification of aquatic toxicity levels. It is inexpensive to use and may be easily adopted by grassroots organizations. The approach is "greener" and more financially and socially sustainable than traditional approaches. The wide use of the approach has the potential to encourage policy innovations for making toxicity monitoring grassroots based and more effective in reducing acute contamination emergencies.     

PCR技术对水中病原体的检测

水中有病毒、细菌、原生动物、蠕虫等多种病原体。常规的检测方法是用大肠菌作为病原体的指示生物,但是大肠菌的生存特性与病毒、原生动物差异较大,难以指示病毒、原生动物的存在与否。对每一种病原体单独进行检测,费时、费力。由于PCR技术具有快速、灵敏、特异的特点,使得它对于水中病原体的检测具有较高的应用价值。