养殖池底泥高效亚硝酸盐去除菌的分离及去除条件研究

以传统水产养殖池塘底泥为材料，从中分离筛选得到31株亚硝酸盐去除菌，从中筛选到1株亚硝酸盐去除能力最强的菌株N—F-0117。该菌株对40mg·L^-1亚硝酸盐的去除率高达92％，对80mg·L^-1亚硝酸盐去除率仍有53％；初始pH值5～10时菌株对亚硝酸盐去除率保持在80％以上；菌株去除亚硝酸盐时最适碳源为蔗糖，浓度为〉2g·L^-1；去除亚硝酸盐时最佳菌液添加浓度为〉0．05％。对菌株进行形态分析、生理生化鉴定，确定该菌株为栖稻黄色单胞菌（Flavimonas oryzihabitans）。

一株粘质沙雷氏菌对污染水体中镉的去除条件研究

水体中重金属污染问题亟待解决,而微生物在水体污染治理中具有显著优势。因此,本文将已从土壤中筛选出的一株对重金属具有耐性的粘质沙雷氏菌(AR1 KX343948.1)用于水体中镉(Cadmium,Cd)污染物的去除。采用控制变量法对粘质沙雷氏菌去除Cd的条件进行了研究,并采用电感耦合等离子法检测耐性菌作用后Cd的浓度变化。结果表明:在实验条件范围内,当Cd浓度为3 mg/L、加菌量为4%、pH为9.4、菌龄为4.5 h及处理时间为96 h时,粘质沙雷氏菌对Cd的去除效果最优,且最高去除率为91.00%。耐性菌对Cd的去除效果在偏低浓度(3~6mg/L)条件下更加显著,对3 mg/L的Cd的去除效率最高,且随加菌量的增加耐性菌对Cd的去除总体呈上升趋势。但在Cd的浓度为12.5 mg/L时,加菌量的增加会抑制耐性菌对Cd的去除。此外,随着处理时间的增加,耐性菌对Cd的去除率不断地增加。

一株养殖水体中亚硝酸盐去除菌的鉴定及其去除条件

【目的】从养殖污泥中分离筛选优良亚硝酸盐去除菌,并对其去除条件进行研究。【方法】从养殖污泥中分离亚硝酸盐去除菌,进一步通过测定比较分离菌株对亚硝酸盐的去除率,筛选优良的亚硝酸盐去除菌,通过API ID32GN细菌鉴定系统以及16S rDNA序列分析法对其进行鉴定,并采用单因子法研究其去除亚硝酸盐的条件。【结果】从养殖污泥中分离筛选了一株优良的亚硝酸盐去除菌AQ-3,其对50 mg/L亚硝酸盐的去除率高达99.47%。菌株AQ-3被鉴定为鲍曼氏不动杆菌(Acinetobacter baumannii)(GenBank登录号:JF751054.1),其16S rDNA序列与基因库中不动杆菌属菌株的16S rDNA序列有99%?100%的同源性,而且与鲍曼氏不动杆菌KF714株(GenBank登录号:AB109775)的亲缘关系最近。菌株AQ-3去除亚硝酸盐的最适初始pH范围为7?9,最佳碳源为乙酸钠和丁二酸钠,而且随着初始菌浓度的不断增大,菌株AQ-3对亚硝酸盐的去除率显著升高;随着亚硝酸盐浓度的不断增大,菌株AQ-3对亚硝酸盐的去除率逐渐降低。【结论】在丰富亚硝酸盐去除菌种质资源的同时,为该菌在养殖水体中的实际应用提供了理论基础。

酸改性膨润土对水中六价铬的去除

采用盐酸对膨润土实施酸性活化制得酸改性膨润土,探究其对水中六价铬去除的最佳条件,影响因素包括酸改性膨润土的投加量以及含铬废液的初始pH值、吸附时间和吸附温度等。实验结果表明,酸改性膨润土的投加量和含铬废液的初始pH对水中六价铬的去除效果的影响较大,最佳条件为:pH=1,吸附时间20 min,吸附温度20℃,投加1%盐酸改性膨润土4.2 g。在最佳条件下,酸改性膨润土对水中Cr6+的去除率达到99%以上。

猪内脂素重组蛋白溶液中内毒素的去除

本试验旨在探索4℃条件下蛋白的上样体积、流速和蛋白浓度对猪内脂素重组蛋白溶液中内毒素的去除效果和蛋白损失量的影响。该研究采用商品化、修饰过的多黏菌素B为介质,特异性地去除蛋白溶液中的内毒素。在4℃条件下,选用不同的上样体积(6、8、10、12 mL)、流速(0.125~0.75 mL/min)和蛋白浓度(0.9、1.2、1.3、1.7 mg/mL)进行内毒素的去除,使用内毒素检测试剂盒定量测定内毒素含量,使用BCA蛋白浓度测定试剂盒进行蛋白浓度的测定。试验结果表明:在4℃条件下,蛋白上样体积12 mL、流速0.125~0.25 mL/min时,内毒素的去除效果最佳,去除率高达99.5%,内毒素的残余量(1 EU/mL)在生物安全范围以内,并且蛋白的回收率高达90~95%。试验结果证明成功去除猪内脂素重组蛋白溶液中的内毒素,为该蛋白的相关功能研究和临床应用提供参考。

Nitrogen removal by three types of bioretention columns under wetting and drying regimes

The behaviors of inorganic nitrogen species in three types of bioretention columns under an intermittently wetting regime were investigated. The mean NH+4—N, NO-3—N and total N(TN) removal efficiencies for the conventional bioretention column(Col. T1) are 71%, 1% and 41%, for layered bioretention column with less permeable soil layer(Col. T2) the efficiencies are 83%, 84% and 82%, and for the bioretention column with submerged zone(Col. T3) the values are 63%, 31% and 53%, respectively. The best nitrogen removal is obtained using Col. T2 with relatively low infiltration rate. Adsorption during runoff dosing and nitrification during the drying period are the primary NH+4—N removal pathways. Less permeable soil and the elevated outlet promote the formation of anoxic conditions. 30%–70% of NO-3—N applied to columns in a single repetition is denitrified during the draining period, suggesting that the draining period is an important timeframe for the removal of NO-3—N. Infiltration rate controls the contact time with media during the draining periods, greatly influencing the NO-3—N removal effects. Bioretention systems with infiltration rate ranging from 3 to 7 cm/h have a great potential to remove NO-3—N.

Degradation of polyvinyl-alcohol wastewater by Fenton’s reagent: Condition optimization and enhanced biodegradability

The pretreatment of refractory polyvinyl-alcohol （PVA） wastewater with low value of CODcr by Fenton＇s reagent was investigated to enhance the biodegradabilily. The effects of operating conditions such as pH of the solution, Fe2＋ dosage, H2O2 dosage, reaction time and initial PVA concentration on the removal efficiency of CODCr were discussed. It is demonstrated that the optimum value of pH for removal of CODcr is 5 and the most suitable dosages of H2O2 （2%） and FeSO4 （10 mg/L） are 5% and 8.0%, respectively. When the initial CODcr value of the PVA water is 760 mg/L, the favorable reaction time is 110 min. Under these optimum conditions, the removal ratio of CODcr is 58.6% 61.4%, and the value of biodegradability （CODB/CODcr） increases markedly from 8.9% 9.7% to 62.6% 68.3%.