High-Rate Biodegradation of Pentachlorophenol by Biofilm Developed in the Immobilized Soil Bioreactor

Karamanev, Dimitre; Samson, Réjean

doi:10.1021/es970366k

Cited by 25 publications

(7 citation statements)

References 16 publications

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“…The highest rates of PCP biodegradation were observed in a reactor with immobilized biofilms developed on soil retained in geotextiles. The reactor was able to convert 22.8 kg PCP m -3 reactor d -1 (Karamanev and Samson 1998). To obtain these high conversion rates, high effluent PCP concentrations of 10 to 20 mg l -1 were required to overcome biofilm diffusion limitations and thus only partial removal of PCP was achieved.…”

Section: Degradation In Engineered Systemsmentioning

confidence: 99%

Microbial degradation of chlorinated phenols

Field

Sierra-Álvarez

2007

Rev Environ Sci Biotechnol

145

102

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Chlorophenols have been introduced into the environment through their use as biocides and as by-products of chlorine bleaching in the pulp and paper industry. Chlorophenols are subject to both anaerobic and aerobic metabolism. Under anaerobic conditions, chlorinated phenols can undergo reductive dechlorination when suitable electron-donating substrates are available. Halorespiring bacteria are known which can use both low and highly chlorinated congeners of chlorophenol as electron acceptors to support growth. Many strains of halorespiring bacteria have the capacity to eliminate ortho-chlorines; however only bacteria from the species Desulfitobacterium hafniense (formerly frappieri) can eliminate para-and meta-chlorines in addition to ortho-chlorines. Once dechlorinated, the phenolic carbon skeletons are completely converted to methane and carbon dioxide by other anaerobic microorganisms in the environment. Under aerobic conditions, both lower and higher chlorinated phenols can serve as sole electron and carbon sources supporting growth. The best studied strains utilizing pentachlorophenol belong to the genera Mycobacterium and Sphingomonas. Two main strategies are used by aerobic bacteria for the degradation of chlorophenols. Lower chlorinated phenols for the most part are initially attacked by monooxygenases yielding chlorocatechols as the first intermediates. On the other hand, polychlorinated phenols are converted to chlorohydroquinones as the initial intermediates. Fungi and some bacteria are additionally known that cometabolize chlorinated phenols.

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Section: Degradation In Engineered Systemsmentioning

confidence: 99%

Microbial degradation of chlorinated phenols

Field

Sierra-Álvarez

2007

Rev Environ Sci Biotechnol

145

102

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“…Therefore, glassware was used wherever possible and tubing made of PTFE. Highporosity polypropylene (Carlson and Silverstein, (1997)), silicone rubber tubes (Zhang et al, 1998) or geotextiles (Karamanev and Samson (1998)), which have been used as solid support in other investigations, were not suitable. For the same reason, no peristaltic pump but a mediumpressure liquid chromatography piston pump with adsorption-resistant materials was used to circulate the solution through the biofilm reactor.…”

Section: System Designmentioning

confidence: 99%

Experimental and modeling approach to study sorption of dissolved hydrophobic organic contaminants to microbial biofilms

2007

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IntroductionBiofilms may significantly influence the distribution of hydrophobic organic compounds (HOC) in heterogeneous aqueous systems and, hence, their residence time, mobility and fate in such systems. When the solid phase provides only poor sorption properties (sewer systems, water supply systems, sand filters, membranes, mineral particles in surface waters and aquifers), the evolution of a microbial biofilm on its surface may provide an important sink and reservoir for hydrophobic contaminants delivered by the aqueous phase. Accumulation of HOC in such biofilms and the increased contact time with bacteria residing in these biofilms may allow adaptation of microorganisms and mineralization of these trace pollutants. For these reasons, the evolution of a biofilm may be essential to retain and to remove HOC in such systems. If these biofilms are detached, however, they could turn into a source for HOC. When the solid phase itself has good sorption properties (soil, activated carbon), a biofilm coverage may act as a barrier that slows down the mass transfer of a hydrophobic compound from the dissolved to the particulate phase. In this case, biofilm growth may hamper rather than improve the removal of HOC.To quantitatively assess the importance of biofilm coatings on surfaces exposed to water for the fate of HOC in these systems, knowledge on the partition coefficients (K D ) as well E-mail address: thorsten.reemtsma@tu-berlin.de (T. Reemtsma). WAT E R R E S E A R C H ] ( ] ] ] ] ) ] ] ] -] ] ]Please cite this article as: Wicke, D., et al., Experimental and modeling approach to study sorption of dissolved hydrophobic organic contaminants to microbial biofilms, Water Res. (2007),

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“…One such reactor is the immobilized soil bioreactor (ISBR) which was originally developed as a membrane bioreactor with a self-contained inoculum (soil) for the mineralization of recalcitrant groundwater contaminants such as pentachlorophenol (Karamanev and Samson, 1998;Karamanev et al, 1999). Its application was then expanded to operation as a methanotrophic bioreactor, for the bioremediation of contaminated groundwater (Ramsay et al, 2001).…”

Section: Introductionmentioning

confidence: 99%

On‐line estimation of dissolved methane concentration during methanotrophic fermentations

Ramsay

2006

Biotech & Bioengineering

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Knowledge of the aqueous phase methane concentration is critical to understanding and controlling process kinetics in methanotrophic bioreactors. Unfortunately since no dissolved methane probe is commercially available, this data must be obtained off-line by the time-consuming gas-liquid partition method. In this study we demonstrate how knowledge of the reactor's k(L)a for oxygen combined with gas phase methane analysis can be used to continuously estimate the aqueous phase concentration of dissolved methane. The on-line estimation was verified in two reactor systems with greatly different values of k (L)a. In both systems the measured and calculated dissolved methane concentrations were in good agreement although dissolved methane was underestimated in both cases. The utility of this methodology was demonstrated by revealing a possible metabolic bottleneck in the model system.

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High-Rate Biodegradation of Pentachlorophenol by Biofilm Developed in the Immobilized Soil Bioreactor

Cited by 25 publications

References 16 publications

Microbial degradation of chlorinated phenols

Microbial degradation of chlorinated phenols

Experimental and modeling approach to study sorption of dissolved hydrophobic organic contaminants to microbial biofilms

On‐line estimation of dissolved methane concentration during methanotrophic fermentations

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