Ethylbenzene,<i>o</i>-Xylene, and BTEX Removal by<i>Sphingomonas sp</i>. D3K1 in Rock Wool-Compost Biofilters

Cho, Eulsaeng; Galera, Melvin Maaliw; Lorenzana, Ariz; Chung, Wook-Jin

doi:10.1089/ees.2007.0144

Cited by 29 publications

(19 citation statements)

References 27 publications

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“…The effect was not due to nutrient limitation, as nutrients were added to the biofilter. Similar behavior was observed by other researchers (Álvarez-Hornos et al, 2008;Cho et al, 2009;Torkian et al, 2003;Vergara-Fernández et al, 2007;Yang et al, 2006). It is possible that excessive microbial growth negatively impacted biofilter performance due to clogging, thereby causing a reduction of the biofilm surface and nonuniform flow of waste gas through the biofilter.…”

Section: Inlet Loading and Gas Compositionsupporting

confidence: 85%

“…Several studies have investigated the effect of gas composition on biofiltration of mixtures. The kinetic parameters of benzene, toluene, ethylbenzene, and xylene degradation are very similar (Abumaizar et al, 1998;Cho et al, 2009;García-Peña et al, 2008;Maliyekkal et al, 2004), so as a first approximation, the biofiltration of BTEX mixtures can be approximated as a single-compound process. To distinguish between individual compounds, a competitive degradation mechanism can be used to describe the process (e.g., Oh et al, 1994).…”

Section: Inlet Loading and Gas Compositionmentioning

confidence: 99%

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Biofiltration for BTEX Removal

Haque

Visscher

Sen

2012

Critical Reviews in Environmental Science and Technology

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Benzene, toluene, ethylbenzene, and xylene (BTEX) biofiltration is an increasingly popular research area because it offers a relatively cheap solution to limit emissions of these toxic agents to the atmosphere. The authors review different technological options for biofiltration, and discuss the main influencing factors including type of packing material, temperature, moisture content and pH of the biofilter packing, influent conditions, and nutrient status. Whenever relevant, these factors are discussed in the context of biofilter ecology, and microbiology of BTEX biofiltration is briefly outlined. The kinetics of BTEX biofiltration are discussed, and the main simulation models developed for this system are presented. Insights on biofiltration of other compounds are also included to complement the available information. The review concludes with a brief outline of some operational challenges.

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Section: Inlet Loading and Gas Compositionsupporting

confidence: 85%

Section: Inlet Loading and Gas Compositionmentioning

confidence: 99%

Biofiltration for BTEX Removal

Haque

Visscher

Sen

2012

Critical Reviews in Environmental Science and Technology

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“…Specifically, this organism classified with the family Sphingomonadaceae (genus unclassified Sphingomonadaceae), found within a Proteobacteria. Microorganisms within this family can degrade a wide variety of both natural and anthropogenic compounds, including PAHs, BTEX and various pesticides (Balkwill et al 1997;Cho et al 2009;Greene et al 2000;Mueller et al 1997;Shi et al 2001;Stolz 2009). However, previous studies have involved either isolations (with testing for degradation) or clone libraries (from a contaminated site or sample), therefore uncertainty remains as to whether these organisms are responsible for contaminant degradation in situ or in a mixed culture.…”

Section: Discussionmentioning

confidence: 99%

Novel aerobic benzene degrading microorganisms identified in three soils by stable isotope probing

et al. 2010

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The remediation of benzene contaminated groundwater often involves biodegradation and although the mechanisms of aerobic benzene biodegradation in laboratory cultures have been well studied, less is known about the microorganisms responsible for benzene degradation in mixed culture samples or at contaminated sites. To address this knowledge gap, DNA based stable isotope probing (SIP) was utilized to identify active benzene degraders in microcosms constructed with soil from three sources (a contaminated site and two agricultural sites). For this, replicate microcosms were amended with either labeled (¹³C) or unlabeled benzene and the extracted DNA samples were ultracentrifuged, fractioned and subject to terminal restriction fragment length polymorphism (TRFLP). The dominant benzene degraders (responsible for ¹³C uptake) were determined by comparing relative abundance of TRFLP phylotypes in heavy fractions of labeled benzene (¹³C) amended samples to the controls (from unlabeled benzene amended samples). Two phylotypes (a Polaromonas sp. and an Acidobacterium) were the major benzene degraders in the microcosms constructed from the contaminated site soil, whereas one phylotype incorporated the majority of the benzene-derived ¹³C in each of the agricultural soils ("candidate" phylum TM7 and an unclassified Sphingomonadaceae).

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“…Such phenomenon might be attributed to the high toxicity of o-xylene, which was considered as the least degradable compound among the three xylene isomers (Cho et al, 2009).…”

Section: Biodegradation Properties Of Btex and Thfmentioning

confidence: 99%