@article {726, title = {Biodegradation of ethylene dibromide (1,2-dibromoethane [EDB]) in microcosms simulating in situ and biostimulated conditions.}, journal = {J Hazard Mater}, volume = {209-210}, year = {2012}, month = {2012 Mar 30}, pages = {92-8}, abstract = {Although 1,2-dibromoethane (EDB) is a common groundwater contaminant, there is the lack of knowledge surrounding EDB biodegradation, especially under aerobic conditions. We have performed an extensive microcosm study to investigate the biodegradation of EDB under simulated in situ and biostimulated conditions. The materials for soil microcosms were collected from an EDB-contaminated aquifer at the Massachusetts Military Reservation in Cape Cod, MA. This EDB plume has persisted for nearly 40 years in both aerobic and anaerobic EDB zones of the aquifer. Microcosms were constructed under environmentally relevant conditions (field EDB and DO concentrations; incubated at 12{\textdegree}C). The results showed that natural attenuation occurred under anaerobic conditions but not under aerobic conditions, explaining why aerobic EDB contamination is so persistent. EDB degradation rates were greater under biostimulated conditions for both the aerobic and anaerobic microcosms. Particularly for aerobic biostimulation, methane-amended microcosms degraded EDB, on average, at a first order rate eight times faster than unamended microcosms. The best performing replicate achieved an EDB degradation rate of 7.0 yr(-1) (half-life (t(1/2))=0.10 yr). Residual methane concentrations and the emergence of methanotrophic bacteria, measured by culture independent bacterial analysis, provided strong indications that EDB degradation in aerobic methane-amended microcosms occurred via cometabolic degradation. These results indicate the potential for enhanced natural attenuation of EDB and that methane could be considered co-substrate for EDB bioremediation for the EDB-contaminated groundwater in aerobic zone.}, keywords = {Aerobiosis, Anaerobiosis, Biodegradation, Environmental, Ethylene Dibromide, Water Microbiology, Water Pollutants, Chemical}, issn = {1873-3336}, doi = {10.1016/j.jhazmat.2011.12.067}, author = {McKeever, Robert and Sheppard, Diane and N{\"u}sslein, Klaus and Baek, Kyung-Hwa and Rieber, Khalil and Ergas, Sarina J and Forbes, Rose and Hilyard, Mark and Park, Chul} } @article {722, title = {Molecular approach to evaluate biostimulation of 1,2-dibromoethane in contaminated groundwater.}, journal = {Bioresour Technol}, volume = {123C}, year = {2012}, month = {2012 May 29}, pages = {207-213}, abstract = {This study investigated the effect of co-substrate amendments on EDB biodegradation under aerobic conditions. Microcosms were established using contaminated soil and groundwater samples and maintained under in situ conditions to determine EDB degradation rates, and the diversity and abundance of EDB degrading indigenous bacteria. After 100days of incubation, between 25\% and 56\% of the initial EDB was degraded in the microcosms, with added jet fuel providing highest degradation rates (2.97{\textpm}0.49yr(-1)). In all microcosms, the quantity of dehalogenase genes did not change significantly, while the number of BTEX monooxygenase and phenol hydroxylase genes increased with jet fuel amendments. These results indicate that EDB was not degraded by prior dehalogenation, but rather by cometabolism with adapted indigenous microorganisms. This is also reflected in the history of the plume, which originated from an aviation gasoline pipeline leak. This study suggests that biostimulation of EDB is possible at aerobic groundwater sites.}, issn = {1873-2976}, doi = {10.1016/j.biortech.2012.05.119}, author = {Baek, Kyunghwa and McKeever, Robert and Rieber, Kahlil and Sheppard, Diane and Park, Chul and Ergas, Sarina J and N{\"u}sslein, Klaus} } @article {728, title = {Performance of a pilot-scale packed bed reactor for perchlorate reduction using a sulfur oxidizing bacterial consortium.}, journal = {Biotechnol Bioeng}, volume = {109}, year = {2012}, month = {2012 Mar}, pages = {637-46}, abstract = {A novel sulfur-utilizing perchlorate reducing bacterial consortium successfully treated perchlorate (ClO$_{4}$$^{-}$) in prior batch and bench-scale packed bed reactor (PBR) studies. This study examined the scale up of this process for treatment of water from a ClO $_{4}$$^{-}$ and RDX contaminated aquifer in Cape Cod Massachusetts. A pilot-scale upflow PBR (\~{}250-L) was constructed with elemental sulfur and crushed oyster shell packing media. The reactor was inoculated with sulfur oxidizing ClO$_{4}$$^{-}$ reducing cultures enriched from a wastewater seed. Sodium sulfite provided a good method of dissolved oxygen removal in batch cultures, but was found to promote the growth of bacteria that carry out sulfur disproportionation and sulfate reduction, which inhibited ClO$_{4}$$^{-}$ reduction in the pilot system. After terminating sulfite addition, the PBR successfully removed 96\% of the influent ClO$_{4}$$^{-}$ in the groundwater at an empty bed contact time (EBCT) of 12 h (effluent ClO$_{4}$$^{-}$ of 4.2 {\textmu}g L(-1)). Simultaneous ClO$_{4}$$^{-}$ and NO$_{3}$$^{-}$ reduction was observed in the lower half of the reactor before reactions shifted to sulfur disproportionation and sulfate reduction. Analyses of water quality profiles were supported by molecular analysis, which showed distinct groupings of ClO$_{4}$$^{-}$ and NO$_{3}$$^{-}$ degrading organisms at the inlet of the PBR, while sulfur disproportionation was the primary biological process occurring in the top potion of the reactor.}, keywords = {Bioreactors, Cluster Analysis, DNA, Bacterial, DNA, Ribosomal, Massachusetts, Microbial Consortia, Molecular Sequence Data, Oxidation-Reduction, Perchloric Acid, Phylogeny, RNA, Ribosomal, 16S, Sequence Analysis, DNA, Sulfites, Sulfur, Water Microbiology, Water Pollutants, Chemical, Water Purification}, issn = {1097-0290}, doi = {10.1002/bit.24354}, author = {Boles, Amber R and Conneely, Teresa and McKeever, Robert and Nixon, Paul and N{\"u}sslein, Klaus R and Ergas, Sarina J} } @article {735, title = {Biological perchlorate reduction in packed bed reactors using elemental sulfur.}, journal = {Environ Sci Technol}, volume = {43}, year = {2009}, month = {2009 Jun 15}, pages = {4466-71}, abstract = {Sulfur-utilizing perchlorate (ClO4-)-reducing bacteria were enriched from a denitrifying wastewater seed with elemental sulfur (S0) as an electron donor. The enrichment was composed of a diverse microbial community, with the majority identified as members of the phylum Proteobacteria. Cultures were inoculated into bench-scale packed bed reactors (PBR) with S0 and crushed oyster shell packing media. High ClO4-concentrations (5-8 mg/L) were reduced to < 0.5 mg/L at an empty bed contact time (EBCT) of 13 h. Low C1O4- concentrations (60-120 microg/L), more typical of contaminated groundwater sites, were reduced to < 4 microg/L at an EBCT of 7.5 h. PBR performance decreased when effluent recirculation was applied or when smaller S0 particle sizes were used, indicating that mass transfer of ClO4- to the attached biofilm was not the limiting mechanism in this process, and that biofilm acclimation and growth were key factors in overall reactor performance. The presence of nitrate (6.5 mg N/L) inhibited ClO4- reduction. The microbial community composition was found to change with ClO4- availability from a majority of Beta-Proteobacteria near the influent end of the reactor to primarily sulfur-oxidizing bacteria near the effluent end of the reactor.}, keywords = {Bacteria, Bioreactors, Environmental Pollutants, Medical Waste Disposal, Oxidation-Reduction, Perchloric Acid, Sulfur}, issn = {0013-936X}, author = {Sahu, Ashish K and Conneely, Teresa and N{\"u}sslein, Klaus R and Ergas, Sarina J} } @article {736, title = {Hydrogenotrophic denitrification and perchlorate reduction in ion exchange brines using membrane biofilm reactors.}, journal = {Biotechnol Bioeng}, volume = {104}, year = {2009}, month = {2009 Oct 15}, pages = {483-91}, abstract = {Halophilic (salt loving), hydrogenotrophic (H(2) oxidizing) denitrifying bacteria were investigated for treatment of nitrate (NO3-) and perchlorate (ClO4-) contaminated groundwater and ion exchange (IX) brines. Hydrogenotrophic denitrifying bacteria were enriched from a denitrifying wastewater seed under both halophilc and non-halophilc conditions. The cultures were inoculated into bench-scale membrane biofilm reactors (MBfRs) with an "outside in" configuration, with contaminated water supplied to the lumen of the membranes and H(2) supplied to the shell. Abiotic mass transfer tests showed that H(2) mass transfer coefficients were lower in brines than in tap water at highest Reynolds number, possibly due to increased transport of salts and decreased H(2) solubility at the membrane/liquid interface. An average NO3- removal efficiency of 93\% was observed for the MBfR operated in continuous flow mode with synthetic contaminated groundwater. Removal efficiencies of 30\% for NO3- and 42\% for ClO4- were observed for the MBfR operated with synthetic IX brine in batch operating mode with a reaction time of 53 h. Phylogenetic analysis focused on the active microbial community and revealed that halotolerant, NO3- -reducing bacteria of the bacterial classes Gamma-Proteobacteria and Sphingobacteria were the metabolically dominant members within the stabilized biofilm. This study shows that, despite decreased H(2) transfer under high salt conditions, hydrogenotrophic biological reduction may be successfully used for the treatment of NO3- and ClO- in a MBfR.}, keywords = {Bacteroidetes, Biofilms, Cluster Analysis, DNA, Bacterial, DNA, Ribosomal, Gammaproteobacteria, Hydrogen, Ion Exchange, Membranes, Molecular Sequence Data, Nitrites, Oxidation-Reduction, Perchloric Acid, Phylogeny, RNA, Ribosomal, 16S, Sequence Analysis, DNA, Water Pollutants, Chemical, Water Purification}, issn = {1097-0290}, doi = {10.1002/bit.22414}, author = {Sahu, Ashish K and Conneely, Teresa and N{\"u}sslein, Klaus and Ergas, Sarina J} }