Transient performance of two-phase partitioning bioreactors treating a toluene contaminated gas stream

Two‐phase partitioning bioreactors (TPPBs) consist of a cell‐containing aqueous phase and an immiscible organic phase that sequesters and delivers toxic substrates to cells based on equilibrium partitioning. The immiscible organic phase, which acts as a buffer for inhibitory substrate loadings, make...

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Published in:Biotechnology and bioengineering 2006-06, Vol.94 (3), p.448-457
Main Authors: Boudreau, Neal G., Daugulis, Andrew J.
Format: Article
Language:English
Subjects:
Achromobacter xylosoxidans
Air Pollution
Bacteria
Biodegradation, Environmental
Biological and medical sciences
Biological treatment of gaseous effluents
Bioreactors
Biotechnology
Biotransformation
Burkholderiaceae - growth & development
Comparative studies
Environment and pollution
Fundamental and applied biological sciences. Psychology
Industrial applications and implications. Economical aspects
Polymers
Reactors
Substrates
toluene
Toluene - chemistry
Toluene - metabolism
transient performance
two-phase partitioning bioreactor
VOCs
Volatile organic compounds
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Daugulis, Andrew J.
description Two‐phase partitioning bioreactors (TPPBs) consist of a cell‐containing aqueous phase and an immiscible organic phase that sequesters and delivers toxic substrates to cells based on equilibrium partitioning. The immiscible organic phase, which acts as a buffer for inhibitory substrate loadings, makes it possible for TPPBs to handle high volatile organic compound (VOC) loadings, and in this study the performance of liquid n‐hexadecane and solid styrene butadiene (SB) polymer beads used as partitioning phases were compared to a single aqueous phase system while treating transient loadings of a toluene contaminated air stream by Achromobacter xylosoxidans Y234. The TPPBs operated as well‐mixed stirred tanks, with total working volumes of 3 L (3 L aqueous for the single‐phase system, 2 L aqueous and 1 L n‐hexadecane for the solvent system, and 2.518 L aqueous volume and 500 g of SB beads for the polymer system). Two 60‐min step changes (7 and 17 times the nominal loading rates, termed “small” and “large” steps, respectively) were imposed on the systems and the performance was characterized by the overall removal efficiencies, instantaneous removal efficiency recovery times (above 95% removal), and dissolved oxygen recovery times. For the small steps, with a nominal loading of 343 g/m3/h increasing to 2,400 g/m3/h, the TPPB system using n‐hexadecane as the second phase performed best, removing 97% of the toluene fed to the system compared with 90% for the polymer beads system and only 69% for the single‐phase system. The imposed large transient gave similar results, although the impact of the presence of a second sequestering phase was more pronounced, with the n‐hexadecane system maintaining much reduced aqueous toluene concentrations leading to significantly improved performance. This investigation also showed that the presence of both n‐hexadecane and SB beads improved the oxygen transfer within the systems. © 2006 Wiley Periodicals, Inc.
doi_str_mv 10.1002/bit.20876
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The immiscible organic phase, which acts as a buffer for inhibitory substrate loadings, makes it possible for TPPBs to handle high volatile organic compound (VOC) loadings, and in this study the performance of liquid n‐hexadecane and solid styrene butadiene (SB) polymer beads used as partitioning phases were compared to a single aqueous phase system while treating transient loadings of a toluene contaminated air stream by Achromobacter xylosoxidans Y234. The TPPBs operated as well‐mixed stirred tanks, with total working volumes of 3 L (3 L aqueous for the single‐phase system, 2 L aqueous and 1 L n‐hexadecane for the solvent system, and 2.518 L aqueous volume and 500 g of SB beads for the polymer system). Two 60‐min step changes (7 and 17 times the nominal loading rates, termed “small” and “large” steps, respectively) were imposed on the systems and the performance was characterized by the overall removal efficiencies, instantaneous removal efficiency recovery times (above 95% removal), and dissolved oxygen recovery times. For the small steps, with a nominal loading of 343 g/m3/h increasing to 2,400 g/m3/h, the TPPB system using n‐hexadecane as the second phase performed best, removing 97% of the toluene fed to the system compared with 90% for the polymer beads system and only 69% for the single‐phase system. The imposed large transient gave similar results, although the impact of the presence of a second sequestering phase was more pronounced, with the n‐hexadecane system maintaining much reduced aqueous toluene concentrations leading to significantly improved performance. 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Bioeng</addtitle><date>2006-06-20</date><risdate>2006</risdate><volume>94</volume><issue>3</issue><spage>448</spage><epage>457</epage><pages>448-457</pages><issn>0006-3592</issn><eissn>1097-0290</eissn><coden>BIBIAU</coden><abstract>Two‐phase partitioning bioreactors (TPPBs) consist of a cell‐containing aqueous phase and an immiscible organic phase that sequesters and delivers toxic substrates to cells based on equilibrium partitioning. The immiscible organic phase, which acts as a buffer for inhibitory substrate loadings, makes it possible for TPPBs to handle high volatile organic compound (VOC) loadings, and in this study the performance of liquid n‐hexadecane and solid styrene butadiene (SB) polymer beads used as partitioning phases were compared to a single aqueous phase system while treating transient loadings of a toluene contaminated air stream by Achromobacter xylosoxidans Y234. The TPPBs operated as well‐mixed stirred tanks, with total working volumes of 3 L (3 L aqueous for the single‐phase system, 2 L aqueous and 1 L n‐hexadecane for the solvent system, and 2.518 L aqueous volume and 500 g of SB beads for the polymer system). Two 60‐min step changes (7 and 17 times the nominal loading rates, termed “small” and “large” steps, respectively) were imposed on the systems and the performance was characterized by the overall removal efficiencies, instantaneous removal efficiency recovery times (above 95% removal), and dissolved oxygen recovery times. For the small steps, with a nominal loading of 343 g/m3/h increasing to 2,400 g/m3/h, the TPPB system using n‐hexadecane as the second phase performed best, removing 97% of the toluene fed to the system compared with 90% for the polymer beads system and only 69% for the single‐phase system. The imposed large transient gave similar results, although the impact of the presence of a second sequestering phase was more pronounced, with the n‐hexadecane system maintaining much reduced aqueous toluene concentrations leading to significantly improved performance. This investigation also showed that the presence of both n‐hexadecane and SB beads improved the oxygen transfer within the systems. © 2006 Wiley Periodicals, Inc.</abstract><cop>Hoboken</cop><pub>Wiley Subscription Services, Inc., A Wiley Company</pub><pmid>16607657</pmid><doi>10.1002/bit.20876</doi><tpages>10</tpages></addata></record>
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subjects Achromobacter xylosoxidans
Air Pollution
Bacteria
Biodegradation, Environmental
Biological and medical sciences
Biological treatment of gaseous effluents
Bioreactors
Biotechnology
Biotransformation
Burkholderiaceae - growth & development
Comparative studies
Environment and pollution
Fundamental and applied biological sciences. Psychology
Industrial applications and implications. Economical aspects
Polymers
Reactors
Substrates
toluene
Toluene - chemistry
Toluene - metabolism
transient performance
two-phase partitioning bioreactor
VOCs
Volatile organic compounds
title Transient performance of two-phase partitioning bioreactors treating a toluene contaminated gas stream
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