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生物强化对MBR系统生物特性及群落结构的影响 被引量:4

Microbial characteristics and community analysis of bioaugmented MBR system
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摘要 采用高效菌强化膜生物反应器对溴氨酸废水进行处理,考察了生物强化前后系统对溴氨酸的降解能力及其内部微生物生理状态变化。并采用核糖体基因间隔序列分析技术(RISA)解析了高效菌投加前后污泥系统的群落变化。实验表明,投菌后在进水负荷增加的条件下,上清液和膜出水的溴氨酸脱色率分别约为50%和65%,相应的COD去除率分别约为25%和50%,和投菌前基本保持一致;TTC-脱氢酶活性和胞外聚合物(EPS)浓度略有波动,但是运行一段时间后即恢复到投菌前水平。群落分析表明高效菌可以在系统中稳定存在,并且不对原菌群结构造成较大影响。 The membrane bioreactor (MBR) bioaugmented by a strain with high degradability for bromamine acid was used for treating bromamine acid wastewater. The biodegradation ability and the physiological state changes were studied before and after the high efficiency strain was added. And the ribosomal intergenic sequence analysis (RISA) was used to show the changes of microbial community during the period. The results show that after inoculation, the decolorization rates of the supernatant and the membrane effluent remained 50% and 65% approximately, and the removal rates of COD were about 25% and 50% , respectively. Although these results were similar to that of the system without high efficiency strain, however the influent load was increased, thus the absolute removal amount was increased. The TTC-dehydrogenase activity and the extracellular polymeric substances (EPS) fluctuated slightly after inoculation, and then were back to the earlier level after a period of operation. Microbial community analysis shows that the inoculated high efficiency strain could steadily survive in the system and did not affect the indigenous populations of the microbial communities.
出处 《环境工程学报》 CAS CSCD 北大核心 2007年第4期70-73,共4页 Chinese Journal of Environmental Engineering
关键词 膜生物反应器 生物强化 核糖体基因间隔序列分析 溴氨酸 membrane bioreactor bioaugmentation ribosomal intergenic sequence analysis bromamine acid
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  • 1牛志卿,刘建荣,吴国庆.TTC-脱氢酶活性测定法的改进[J].微生物学通报,1994,21(1):59-61. 被引量:49
  • 2朱南文,闵航,陈美慈,赵宇华.TTC─脱氢酶测定方法的探讨[J].中国沼气,1996,14(2):3-5. 被引量:95
  • 3沈东升,徐向阳,冯孝善.厌氧颗粒污泥对五氯苯酚的吸附、解吸和生物降解研究[J].环境科学,1996,17(1):20-23. 被引量:12
  • 4[1]Makinen PM, Theno TJ, Ferguson JF, Ongerth JE, Puhakka JA. Chlorophenol toxicity removal and monitoring in aerobic treatment: recovery from process upsets [J]. Environ. Sci. Technol., 1993, 27(7):1434~1439.
  • 5[2]Limbergen H V, Top E M, Verstraete W. Bioaugmentation in activated sludge: current features and future perspectives [J]. Appl. Microbiol.Biotechnol., 1998,50:16~23.
  • 6[3]Boon N, Goris J, de Vos P, Verstraete W, Top EM. Bioaugmentation of activated sludge by an indigenous 3-chloroaniline-degrading Comamonas testosterone strain I2gfp [J]. Appl. Environ. Microbiol., 2000, 66(7):2906~2913.
  • 7[4]Melin E S, Ferguson J F,Puhakka J A. Pentachlorophenol biodegradation kinetics of an oligotrophic fluidezed-bed enrichment culture [J]. Applied Microbiology and Biotechnology, 1997, 47(6): 675~682.
  • 8David C W, Susan D S, David B R. The genus Sphingomonas:physiology and ecology [ J ]. Current Opinion in Biotechnology,1996, 7:301-306.
  • 9Busse H J, Kampfer P, Denner E B M. Chemotaxonomic characterization of Sphingomonas [ J ]. Journal of Industrial Microbiology & Biotechnology, 1999, 23: 242-251.
  • 10Stolze A, Schmidt M C, Denner E B M. Description of Sphingomonas xenophaga sp. nov. for strains BN6T and N, N which degrade xenobiotic aromatic compounds [J]. International Journal of Systematic and Evolutionary Microbiology, 2000, 50:35-41.

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