Effcient degradation of lube oil by a mixed bacterial consortium

A laboratory study was performed to assess the biodegradation of lube oil in bio-reactor with 304# stainless steel as a biofilm carrier. Among 164 oil degrading bacterial cultures isolated from oil contaminated soil samples, Commaonas acidovorans Px1, Bacillus sp. Px2, Pseudomonas sp. Px3 were selected to prepare a mixed consortium for the study based on the e ciency of lube oil utilization. The percentage of oil degraded by the mixed bacterial consortium decreased slightly from 99% to 97.2% as the concentration of lube oil was increased from 2000 to 10,000 mg/L. The degradation of TDOC (total dissolved organic carbon) showed a similar tendency compared with lube oil removal, which indicated that the intermediates in degradation process hardly accumulated. Selected mixed bacterial consortium showed their edge compared to activated sludge. Scanning electron microscopy (SEM) photos showed that biofilms on stainless steel were robust and with a dimensional framework constructed by EPS (extracellular polymeric substances), which could promote the biodegradation of hydrocarbons. The increase of biofilm followed first-order kinetics with rate of 0.216 g glucose/(cm2 day) in logarithm phase. With analysis of Fourier transform infrared spectroscopy (FT-IR) and gas chromatography-mass spectrometry (GC-MS) combined with removal of lube oil and TDOC, mixed bacterial consortium could degrade benzene and its derivatives, aromatic ring organic matters with a percentage over 97%.     

Efficient degradation of lube oil by a mixed bacterial consortium

A laboratory study was performed to assess the biodegradation of lube oil in bio-reactor with 304# stainless steel as a biofilm carrier. Among 164 oil degrading bacterial cultures isolated from oil contaminated soil samples, Commaonas acidovorans Px1, Bacillus sp. Px2, Pseudomonas sp. Px3 were selected to prepare a mixed consortium for the study based on the efficiency of lube oil utilization. The percentage of oil degraded by the mixed bacterial consortium decreased slightly from 99% to 97.2% as the concentration of lube oil was increased from 2000 to 10,000 mg/L. The degradation of TDOC (total dissolved organic carbon) showed a similar tendency compared with lube oil removal, which indicated that the intermediates in degradation process hardly accumulated. Selected mixed bacterial consortium showed their edge compared to activated sludge. Scanning electron microscopy (SEM) photos showed that biofilms on stainless steel were robust and with a dimensional framework constructed by EPS (extracellular polymeric substances), which could promote the biodegradation of hydrocarbons. The increase of biofilm followed first-order kinetics with rate of 0.216 μg glucose/(cm2·day) in logarithm phase. With analysis of Fourier transform infrared spectroscopy (FT-IR) and gas chromatography-mass spectrometry (GC-MS) combined with removal of lube oil and TDOC, mixed bacterial consortium could degrade benzene and its derivatives, aromatic ring organic matters with a percentage over 97%.     

Biodegradation of benzo[a]pyrene in soil by Mucor sp. SF06 and Bacillus sp. SB02 co-immobilized on vermiculite

Two indigenous microorganisms, Bacillus sp. SB02 and Mucor sp. SF06, capable of degrading polycyclic aromatic hydrocarbons （PAHs） were co-immobilized on vermiculite by physical adsorption and used to degrade benzo[a] pyrene （BaP）. The characteristics of BaP degradation by both free and co-immobilized microorganism were then investigated and compared. The removal rate using the immobilized bacterial-fungal mixed consortium was higher than that of the freely mobile mixed consortium. 95.3% of BaP was degraded using the co-immobilized system within 42 d, which was remarkably higher than the removal rate of that by the free strains. The optimal amount of inoculated co-immobilized system for BaP degradation was 2%. The immobilized bacterial-fungal mixed consortium also showed better water stability than the free strains. Kinetics of BaP biodegradation by co-immobilized SF06 and SB02 were also studied. The results demonstrated that BaP degradation could be well described by a zero-order reaction rate equation when the initial BaP concentration was in the range of 10--200 mg/kg. The scanning electronic microscope （SEM） analysis showed that the co-immobilized microstructure was suitable for the growth of SF06 and SB02. The mass transmission process of co-immobilized system in soil is discussed. The results demonstrate the potential for employing the bacterial-fungal mixed consortium, co-immobilized on vermiculite, for in situ bioremediation of BaP.     

土壤中多环芳烃微生物降解能力模拟

为了揭示微生物菌种(组合)对土壤中PAHs(多环芳烃)降解率的影响以及不同类型PAHs抗微生物降解能力的差异,分析了北京市6个不同环境功能区土壤中微生物种类及其分布特征,从中筛选出部分微生物菌种对典型PAHs和原油进行降解模拟试验,对比分析微生物对不同PAHs降解能力的差异.结果表明:① 不同菌种组合对PAHs的降解能力存在明显差异,与假单胞菌属、无色杆菌、短稳杆菌混合菌相比,假单胞菌属、无色杆菌、短稳杆菌和微杆菌混合菌对PAHs的降解率高0.6%~4.5%;② 在相同降解条件下,不同PAHs的降解率存在明显差异,在单体培养基中,LMW PAHs(低环数PAHs)的降解率在25.3%以上,而HMW PAHs(高环数PAHs)的降解率都小于20.1%;③ 在单体培养基与混合培养基中PAHs的降解能力也存在一定差别,单体培养基中PAHs的降解率较混合培养基中高4.2%~26.6%;④ 无论在单体培养基中,还是混合培养基中这些化合物的降解率均存在随着降解时间的增加而增大的现象;⑤ 在原油培养基中不同PAHs的降解率更为复杂,并且出现了中低分子量PAHs降解率随降解时间增加反而降低的假象,这可能是由于随着时间增加,微生物对PAHs的降解能力加强,原油中含烷基的PAHs基团降解或HMW PAHs被微生物降解产生LMW PAHs中间产物造成.研究显示,假单胞菌属、无色杆菌、短稳杆菌和微杆菌对HMW PAHs和LMW PAHs均有明显的降解效果,但不同PAHs的降解率存在明显的差异,即使是同一单体化合物,在单体培养基、混合培养基和原油培养基三种不同的降解条件下,其降解率也具有不同程度的差别.      

紫外辐射下的生物降解及微生物群落的变化

分别采用一体式循环床紫外光/生物膜反应器（PCBBR）和气升式内循环的紫外光/生物膜反应器（ILPBR）,用于苯酚、2,4,6-三氯酚（TCP）和抗生素药物磺胺甲恶唑（SMX）的降解.结果表明,苯酚、TCP和SMX在紫外光解与生物降解的共同作用下,其去除速率分别达到0.65、0.11和0.17 mg.（L.min）–1...     

生物浮选法处理含油污泥

利用从石油污染物中分离的一组微生物菌株对胜利油田含油污泥进行了生物浮选处理,探讨了处理过程中温度、稀释率、投加菌量及加糖量等因子对油去除率的影响及组合菌株与单一菌株处理效果的差异。通过实验获得生物浮选最佳运行参数为:温度40℃,稀释率98%,加菌量3.75%,加糖量0.25%,在该参数运行条件下,原油去除率可达95%以上。使用混合菌株进行生物浮选有利于回收原油中含油量的提高。     

光催化与生物膜直接耦合降解4-氟苯酚废水

为了实现4-氟苯酚（4-FP）废水的快速持续降解,本文构建了光催化与生物膜直接耦合系统.该耦合系统由N掺杂TiO₂涂覆光催化光纤束、生物膜、核孔膜和紫外-可见LED光源构成.实验研究了单独光催化、单独微藻生物膜及光催化-生物膜耦合3种体系对4-FP的降解性能.研究发现：光催化系统降解4-FP速率慢、脱氟效率低,12h内降解率为94.3%,脱氟率仅为24.7%.微藻生物膜在第一个周期内对4-FP的降解性能高于单独光催化,10h内降解率达到98.9%,脱氟率达到90.9%,但3个周期后4-FP降解率降低至75.5%,脱氟率降低至69.5%.在耦合系统中,生物膜中微生物种群发生了自适应调整,富集了大量的红球菌、假单胞菌和无色杆菌,导致了光催化、生物降解及光合作用三者亲密协作,实现了4-FP快速持续地降解,运行12个周期后,5h即可将4-FP完全降解,同时溶解有机碳及脱氟率分别达到89.4%和78.3%.     

砂土中柴油的微生物降解研究

从加油站污染土壤中筛选出对柴油具有较强降解能力的菌株,比较研究菌株及菌群降解柴油的差异,探讨植物苜蓿和芥菜对菌株降解柴油污染物的影响.结果表明:①菌株Q18和菌群对砂土中柴油都具有较强的降解能力,菌群对柴油的降解率明显高于菌株Q18.菌株Q18 和菌群在5 d内对柴油的总降解率分别为40.29%和54.15%.与菌株Q18降解柴油相比,菌群主要是强化了中、长链烷烃化合物的降解.②在砂土中,苜蓿和芥菜都能显著地强化菌株Q18对柴油的降解,但苜蓿强化菌株Q18降解柴油的能力强于芥菜. 5 d内菌株Q18-芥菜和菌株Q18-苜蓿复合体系对柴油总降解率分别达到60.05%和56.68%.③菌群和苜蓿及芥菜复合体系降解柴油的能力也有显著提高,但芥菜强化菌群降解柴油的能力强于苜蓿.5 d内菌群-芥菜和菌群-苜蓿复合体系对柴油总降解率分别为75.53%和70.50%.      

Adaptability of microbial inoculators and their contribution to degradation of mineral oil and PAHs

Five dominant bacteria strains（A cetobacter sp., Alcdigenes sp., Micrococcus sp., Arthrobacter sp. and Bacillus sp.） and five fungi strains （Cephalosporium sp. Ⅰ, Cephalosporlum sp. Ⅱ, Aspergillus sp. Ⅰ, Aspergillus sp. Ⅱ and Fusarium sp.） isolated from petroleum-contaminated soil were used to assess the potential capability of mineral oil and PAH enhanced degradation separately and jointly using the batch liquid medium cultivation with diesel oil spiked at 1000 mg/L. The experiment was performed on a reciprocal shaker in the darkness at 25℃ to 30℃ for 100 d. The dynamic variation in the activity of microbial inoculators in each treatment and the degradation of the target pollutants during the period of experiment were monitored. Results showed a more rapid biodegradation of mineral oil and PAHs at the beginning of the experiment （about 20 d） by dominant bacteria, fungi and their mixture than that of the indigenous microorganisms, however, thereafter an opposite trcnd was exhibited that the removal ratio by indigenous microorganisms was superior to any other dominant treatments and the tendency lasted till the end of the experiment, indicating the limited competitive capability of dominant microorganisms to degrade the contaminants, and the natural selection of indigenous microorganisms for use in the removal of the contaminants. At the end of the experiment, the removal ratio of mineral oil ranged from 56.8 % to 79.2 % and PAHs ranged from 96.8 % to 99.1% in each treatment by microbial inoculators,     

微塑料对近岸多环芳烃降解菌群结构及其降解能力的影响

近海岸微塑料的污染问题日益突出,对周围生态环境造成了严重的影响.微塑料研究主要集中于微塑料在生物体内的积累,而有关微塑料对微生物生态的影响研究还很少.本文针对受微塑料影响较严重的近岸环境,从受石油污染的近岸水体中富集驯化得到功能菌群菲降解菌群MB1,探究微塑料对近岸菲降解菌群结构及降解能力的影响.结果表明:微塑料的添加在一定程度上促进菲的降解;SEM扫描电镜分析进一步显示微生物附着在微塑料上并分泌丝状物质;采用Illumina序列分析添加微塑料后菌群结构的变化,发现培养6 d后在有添加微塑料的体系中优势菌属以Glaciecola为主,而未添加的对照组中优势菌属是Rhdovulum,说明微塑料的添加可明显改变降解多环芳烃的菌群结构,进而影响污染物的降解能力.     

Biodegradation of N,N-dimethylacetamide by Rhodococcus sp. strain B83 isolated from the rhizosphere of pagoda tree

The biodegradation characteristic and potential metabolic pathway for removal of environmental N,N-dimethylacetamide (DMAC) by Rhodococcus sp. strain B83 was studied. Rhodococcus sp. strain B83 was isolated from the rhizosphere of a pagoda tree and proved capable of utilizing DMAC as sole source of carbon and nitrogen. Batch culture studies showed that strain B83 could tolerate up to 25 g/L DMAC and showed distinct growth on possible catabolic intermediates except for acetate. The nitrogen balance analysis revealed that approximately 71% of the initial nitrogen was converted to organic nitrogen. DMAC degradation has led to accumulation of acetate and organic nitrogen, meanwhile traces of nitrate and ammonia was build-up but without nitrite. The growth of strain B83 could be inhibited by adding exogenous acetate. By means of the assay of enzymatic degradation of DMAC, several catabolic intermediates at different intervals were observed and identified. Based on the results obtained from culture solution and enzymatic degradation assay, a detailed pathway is proposed for DMAC biodegradation.     

萘厌氧降解菌群的富集及氧化还原介体的强化

为揭示氧化还原介体（ROMs）对萘厌氧降解的强化作用,以萘为唯一碳源富集到中温萘厌氧降解菌群.通过Illumina MiSeq测序对接种污泥和富集培养物进行了细菌群落结构解析,并考察了固定化蒽醌-2,6-二磺酸（AQDS）、蒽醌-2-磺酸（AQS）和腐殖酸强化萘厌氧降解的特征.Illumina MiSeq测序结果表明,Pseudomonas、Thauera、和Georgfuchsia是该富集培养物中的优势萘降解菌,其相对丰度分别为52.4%、13.8%和17.6%.在污泥接种量为0.23g/L和萘初始浓度10mg/L条件下,富集菌群9d内对萘的降解率约为64%.ROMs强化试验结果表明,3种ROMs对萘的厌氧降解均有一定的促进作用.其中,AQDS的强化效果最为显著,当AQDS浓度为0.8mmol/L,培养至第7d时,萘的去除率为92.0%,比同期的对照组高1.2倍.此外,硝酸盐对ROMs强化萘厌氧降解的影响研究结果表明,在NaNO₃浓度为0~0.8g/L范围内,萘的降解速率随着硝酸盐浓度增加呈现先增加后降低的趋势.当NaNO₃浓度为0.6g/L时,萘的去除率在第6d就达到了91.0%,比对照组提高了15.2%.由此可见,在厌氧条件下添加适量硝酸盐可提高ROMs对萘降解的强化效果.     

复合菌群生物强化削减NPEO内分泌干扰毒性的试验研究

印染废水中的壬基酚聚氧乙烯醚(nonylphnol polyethylene ether, NPEO)在生化处理过程中会产生雌激素活性更强的壬基酚(NP)等中间产物,导致处理后印染废水内分泌干扰毒性升高.为探索以NPEO和NP为降解靶点进行菌群生物强化脱毒的可行性,分别以NPEO和NP驯化富集印染活性污泥,并将得到的降解菌群以单独和组合投加方式进行生物强化试验,考察强化控毒效果.结果表明：(1)NPEO降解菌群(NPEB)和NP降解菌群(NPB)中的优势菌均为Proteobacteria,二者对10 mg/L NPEO和NP的48 h去除率均高于98%.(2)单独或组合投加5 mg/L的NPEB和NPB至混合液悬浮固体浓度(MLSS)为500 mg/L的活性污泥体系,均能显著提升活性污泥对不同浓度(10和1 mg/L) NPEO的降解性能,大幅缩短NPEO降解过程中雌激素活性的变化周期,并使体系的雌激素活性维持在较低水平.(3)当降解体系中加入1 000 mg/L葡萄糖作为额外碳源时,NPB的强化性能被完全抑制,而NPEB在降解性能受抑的情况下仍能增强活性污泥的NPEO降解速率并缩短控...     

分离海洋不动杆菌及其对石油烃降解性能研究

石油降解菌在石油污染生物修复技术中起到非常重要的作用。本研究分别以渤海湾油污区采集的水样,油样,水油泥混合样为材料富集分离石油降解菌,对其进行生理生化及分子生物学鉴定,并采用GC-MS测定烷烃、环烃、芳香烃等石油烃组分的变化。其中3株菌具有较高石油烃降解能力,16SrRNA序列分析表明该3株菌均与不动杆菌属（Acinetobacter）有99%序列相似性,可初步鉴定为不动杆菌属（Acinetobacter）。3株菌的石油烃降解能力依次为Tust-DM21＞Tust-DC12＞Tust-DW04,对原油成分的降解效果依次为烷烃＞芳香烃＞环烃。其中菌株Tust-DM21为一株高效石油烃降解菌,28℃于富集培养基培养10 d后,对烷烃（C10~C30）的降解率可达98%,对芳香烃和环烃的降解率达88%。研究表明,Tust-DM21菌株对烷烃,环烃,芳香烃都有较强的降解能力,是一株具有较好开发前景的石油降解菌。     

紫外辐射与生物膜同步耦合降解喹啉

紫外辐射光解与生物降解同步耦合的气升式内循环反应器用于喹啉的降解.实验过程中分别采用单独紫外光解、单独生物降解和紫外光解与生物降解同步耦合的方法对喹啉进行降解.结果表明,喹啉在紫外光解与生物降解同步耦合的作用下,其降解速率明显提高.喹啉降解动力学分析结果表明,喹啉的生物降解可以用有抑制性的Haldane模型描述.相比生物降解过程,单独紫外光解对喹啉的降解速率可以忽略,但将紫外辐射与生物降解耦合在一起后,可以提高喹啉的最大降解速率近1倍并减小抑制常数36%,同时还可以提高喹啉的矿化程度.     

Synergistic removal of aniline by carbon nanotubes and the enzymes of Delftia sp. XYJ6

Synergistic removal of aniline by carbon nanotubes and the enzymes of Delftia sp. XYJ6, a newly isolated bacterial strain for biodegrading aniline, was investigated. It showed that biodegradation rate of aniline was increased with the augment of protein concentration in cell-free extract of Delftia sp. XYJ6. The adsorption amount of aniline by multi-walled carbon nanotubes (MWCNTs) was slightly higher than that by single-walled carbon nanotubes (SWCNTs), however the adsorption amount of protein of Delftia sp. XYJ6 by MWCNTs was lower than that by SWCNTs. Much more amount of aniline could be removed by CE of Delftia sp. XYJ6 in the presence of SWCNTs than MWCNTs, which indicated that an efficient reaction between aniline and enzymes of Delftia sp. XYJ6 on the surface of SWCNTs played a key role in the rapid enzymatic biodegradation of aniline. This study is not previously reported and may be useful in basic research and the removal of aniline from wastewater.     

Biodegradation kinetic of organic compounds of acrylic fiber wastewater in biofilm

IntroductionBiofilmkineticmodelplaysanimportantroleintherationaloptimizationofbiofilmreactordesign ,operationandresearch .Whereas,itsapplicationinthedesignoffull scaleoperationsisfarfromreachingtheacceptancelevelbecausewhichiscomplicatedmathematicalentities.Theapproachofillustrationloadingcurvecanbeusedtodesignthebiofilmreactorandavoidthecomplexsolutionforequationgroupofthemodel.Fixedbiofilmsystemshavevariousadvantagesovermoreconventionalactivatedsludgeprocess,includingtheabilitytosupportavari…     

大豆磷脂对不动杆菌降解硝基苯的影响

研究了液相体系中不同用量的大豆磷脂对不动杆菌降解硝基苯的影响.大豆磷脂可以作为不动杆菌的唯一碳源,在一定程度上支持其生长.实验表明,在适宜不动杆菌生长的400 mg/L硝基苯质量浓度下,加入500 mg/L大豆磷脂对不动杆菌生物量和硝基苯的完全降解时间无影响,而加入250,1 000 mg/L大豆磷脂却延缓了细菌的生长和硝基苯的降解,这主要是由于它与硝基苯形成竞争代谢或是由于硝基苯在胶束中的分配降低了其生物可利用性;当硝基苯质量浓度约为600 mg/L时,加入大豆磷脂(高于临界胶束浓度)显著促进了细菌的生长和硝基苯的降解,并且促进效果与加入量成正比,这主要是因为胶束的分配作用对硝基苯产生了脱毒效果,另外大豆磷脂作为辅助碳源增加了生物量,也促进了对硝基苯的代谢分解.      

嗜盐菌群在甲苯降解过程中群落结构的变化解析

从胜利油田的高盐油污土壤中富集到1个高效降解BTEX(苯、甲苯、乙苯、二甲苯)的嗜盐菌群,分析了菌群在甲苯降解过程中的群落结构变化.结果表明,该菌群在5%盐度下可完全降解200mg/L甲苯.PCR-DGGE图谱显示,随着甲苯的加入,该菌群的优势种属由Bacillus sp.和Bacillus aquimaris转变为Thalassospira xiamenensis、Pseudomonas stutzeri、Virgibacillus sp.和Bacillus sp..这4种微生物在整个降解过程中稳定存在,且在降解完成后24h内没有衰亡的迹象.另外,该菌群可以降解菲,显示了降解多种芳香族化合物的能力.     

管材对供水管网生物膜微生物种群多样性的影响

研究了3种管材(灰口铸铁管、镀锌管和不锈钢复合管)对管网生物膜微生物种群多样性的影响.采用R2A平板培养计数可培养细菌、荧光定量PCR计数细菌总数、流式细胞法确定活菌比例、扫描电镜观察生物膜形态,高通量测序研究管段生物膜微生物种群多样性.研究结果表明:灰口铸铁管可培养菌数和细菌总数都最高,其次是镀锌管,不锈钢复合管可培养菌数和细菌总数都最少,但活菌比例方面镀锌管活菌比例高于灰口铸铁管和不锈钢复合管.扫描电镜结果与可培养菌数及细菌总数结果一致,即灰口铸铁管细菌量最高,不同管材管壁生物膜细菌形态皆以球菌和杆菌为主,并无显著差异.微生物种群多样性结果显示:灰口铸铁管生物膜种群多样性最高,镀锌管生物膜种群多样性相对较为单一,不锈钢复合管生物膜种群多样性最低.饮用水管网生物膜种群以变形菌门为主,各管道变形菌门都高达90%以上,不同管材生物膜细菌群落组成有很大差异.本研究结果对今后饮用水供水管段材料的选取具有指导性意义.