嗜热厌氧乙醇菌在纤维素酒精生产中的作用

以热纤维梭菌 (Clostridium thermocellum LQRI)和嗜热厌氧乙醇菌(Thermoanaerobacter ethanolicus X514和Thermoanaerobacter pseudoethanolicus 39E)为对象,以不同浓度纤维素Avicel为底物,研究嗜热厌氧乙醇菌加入LQR...     

一株发酵纤维素产丁酸菌及其代谢动力学特性

为开发降解纤维素产丁酸菌的种子资源,从牛粪、猪粪堆肥、玉米地土壤和腐木混合物的富集样品中分离得到一株厌氧降解纤维素产丁酸菌.该菌株细胞呈杆状,长7.1~9.1μm,直径1.2μm左右,经鉴定为丁酸梭菌(Clostridium butyricum),命名为C. Butyricum DCB.在35℃条件下,菌株DCB在纤维二糖液体培养基中的最大比生长速率为0.6536h^-1,世代时间为1.06h,纤维二糖降解速率为0.1g/(L·h),丁酸生成速率为0.06g/(L·h).该菌株利用纤维素发酵产丁酸的转化率高达0.23g/g,具有良好的开发前景.     

对生态系统中分离获得的菌种进行优势种群测定的方法学探讨：一株优势纤维分解菌的确定

两年内７次从同一个以杨木木屑为原料的厌氧发酵罐的高稀释度发酵液中分离出一株中温纤维分解菌，即新种阿氏梭状芽孢杆菌（Ｃｌｏｓｔｒｉｄｉｕｍａｌｄｒｉｃｈｉｉ）。从细菌计数高且能反复分离获得这两个特点，可以断定阿氏梭状芽孢杆菌在该生态系统中曾是一个优势种群。经菌落及菌体形态学观察，以及用首次分离的菌株所作的多价抗血清酶联免疫吸附试验（ＥＬＩＳＡ），确定７次分离菌株为同一菌种，从而证实阿氏梭状芽孢杆菌在１９８６年９月至１９８８年８月间，曾是该厌氧发酵罐中每毫升含菌高达１０６─１０７的优势纤维分解菌。     

Effect of hydraulic retention time on the hydrogen yield and population of Clostridium in hydrogen fermentation of glucose

The conversion of glucose to hydrogen was evaluated using continuous stirred tank reactor at pH 5.5 with various hydraulic retention times (HRT) at 30°C. Furthermore, the population dynamics of hydrogen-producing bacteria was surveyed by fluorescence in-situ hybridization using probe Clost IV targeting the genus Clostridium based on 16S rRNA. It was clear that positive correlation was observed between the cells quantified with probe Clost IV and hydrogen yield of the respective sludge. The numbers of hydrog...     

糖厂污泥中高效产氢菌的分离鉴定及产氢优化

从甘蔗糖厂污泥样品中,分离纯化得到一株革兰氏阳性厌氧产氢菌。经16S rDNA分子生物学鉴定,该菌株为Clostridium sp.60E(注册号:JF708079)。对该菌株生长及产氢特性的研究发现,其产氢主要发生在细胞生长对数期的中后期和稳定期。温度及pH值单因素实验显示,Clostridium sp.60E为一株中温产氢菌,有较好的耐酸能力。采用正交实验研究方法优化产氢条件,发现起始pH值为5,培养温度为35℃,碳源选择葡萄糖时,其总产氢量最高可达到(208±8.01)mL H2/100 mL培养基,比优化前提高了142%,产氢纯度最高达到55.32%,最高产氢速率为(188±8.72)mL H2/(L.h)、15.99 mmo(l H)2g(/dry cell.h)。以上研究表明,从糖厂污泥中筛选的Clostridium sp.60E是一株良好的厌氧发酵产氢菌,将其应用于废水处理,可以实现有机废水的高效制氢,是实现废水和有机废物资源化的一条有效途径。     

产气荚膜梭菌（示踪剂）的水体稀释扩散试验

产气荚膜梭菌具有抗污染，在好氧，厌氧状态下存活期长，不自行繁殖的特性。用产气荚膜力为示踪剂的水体稀释扩散。试验结果表明：排污口下游不同位置产气荚膜梭菌的浓度实测值与理论计算吻合，并可以替代罗丹明Ｂ。     

An Italian Study on Cryptosporidium and Giardia in Wastewater, Fresh Water and Treated Water

Cryptosporidium oocysts and Giardia cysts has been isolated from waters worldwide. In Italy, studies on these parasites in the environment are still limited due to absence of epidemiological evidence and difficulty of adequate methodologies of sampling and analysis. The new Drinking Water Directive 98/83/CE states that Cryptosporidium has to be determined in water intended for human consumption if Clostridium perfringens is detected. This investigation contributes to the knowledge of both Cryptosporidium and Giardia occurrences in Italian aquatic environments through a two-year monitoring program. In addition, indicator bacteria and Clostridium perfringens were monitored in sewage, surface waters, drinking water, and swimming pools and possible correlations were calculated among all the selected parameters. Cysts and oocysts were detected in sewage and surface water and Giardia numbers always prevailed over Cryptosporidium. The parasites were not detected in drinking water, while a positive sample was obtained from the analysis of swimming pools. Pearsons correlation coefficients evidenced a reciprocal correlation between both the protozoa and the Enterococci counts.     

产氢菌Clostridium butyricum P22的分离鉴定及其产氢特性研究

从连续生物制氢反应器中分离得到高效产氢细菌P22,利用微生物自动鉴定仪并结合菌株16S rDNA序列分析,将其鉴定为Clostridium butyricum P22.同时还进一步研究了碳源、氮源、初始pH值和培养温度对菌株P22产氢活性的影响.结果表明:该菌株能利用多种碳源氮源产氢,当以葡萄糖作为产氢底物时,其最大产...     

Clostridium papyrosolvens厌氧发酵产氢研究

采用分批培养研究了从高浓度厌氧产氢活性污泥中筛选的优势菌种Clostridium papyrosolvens的发酵产氢能力.结果表明:该菌有较强的高糖耐受性和耐酸性,当葡萄糖浓度为30 g/L、pH阶段性控制在4.5时,发酵44 h葡萄糖消耗率为83.7%,总产气量达到3 081.3 mL/L,最高产气率为187.5 mL L-1 h-1,氢气含量为67.5%,比产氢率达1.06 mol(H2)/mol(葡萄糖).研究中选用了廉价的发酵产氢培养基,以玉米浆为氮源,以还原铁粉作氧化还原电位控制剂,省去了牛肉膏、蛋白胨等昂贵氮源以及L-半胱氨酸、维生素、无机离子等高成本组分,显著降低了纯菌发酵的培养基成本,获得了较好的产氢效果.图5表2参23     

Biohydrogen production by Clostridium butyricum and Rhodopseudomonas palustris in Co-cultures

This study evaluated biohydrogen production by co-culture of Clostridium butyricum and Rhodopseudomonas palustris. C. butyricum and R. palustris were grown separately and together as batch cultures. Hydrogen production, growth, NH₄-N, total volatile fatty acid production, and sucrose degradation were monitored. The hydrogen production of the co-culture produced 562 ml, R. palustris 426 ml, and C. butyricum 333 ml. The co-culture produced 2.16 mol H₂/mol sucrose, C. butyricum and R. palustris produced 1.77 and 1.64 mol H₂/mol sucrose, respectively. The co-culture was more efficient in the hydrogen production. Therefore, the co-culture is a good method for biohydrogen fermentation.