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Alan A. Dispirito - One of the best experts on this subject based on the ideXlab platform.
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Growth of Rhodospirillum rubrum on synthesis Gas: Conversion of CO to H2 and poly‐β‐hydroxyalkanoate
Biotechnology and bioengineering, 2007Co-Authors: Young S., J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
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Growth of rhodospirillum rubrum on synthesis Gas conversion of co to h2 and poly β hydroxyalkanoate
Biotechnology and Bioengineering, 2007Co-Authors: J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
J. Smeenk - One of the best experts on this subject based on the ideXlab platform.
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Growth of Rhodospirillum rubrum on synthesis Gas: Conversion of CO to H2 and poly‐β‐hydroxyalkanoate
Biotechnology and bioengineering, 2007Co-Authors: Young S., J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
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Growth of rhodospirillum rubrum on synthesis Gas conversion of co to h2 and poly β hydroxyalkanoate
Biotechnology and Bioengineering, 2007Co-Authors: J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
Thomas A. Bobik - One of the best experts on this subject based on the ideXlab platform.
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Growth of Rhodospirillum rubrum on synthesis Gas: Conversion of CO to H2 and poly‐β‐hydroxyalkanoate
Biotechnology and bioengineering, 2007Co-Authors: Young S., J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
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Growth of rhodospirillum rubrum on synthesis Gas conversion of co to h2 and poly β hydroxyalkanoate
Biotechnology and Bioengineering, 2007Co-Authors: J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
Karl M. Broer - One of the best experts on this subject based on the ideXlab platform.
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Growth of Rhodospirillum rubrum on synthesis Gas: Conversion of CO to H2 and poly‐β‐hydroxyalkanoate
Biotechnology and bioengineering, 2007Co-Authors: Young S., J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
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Growth of rhodospirillum rubrum on synthesis Gas conversion of co to h2 and poly β hydroxyalkanoate
Biotechnology and Bioengineering, 2007Co-Authors: J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
Clint J. Kisting - One of the best experts on this subject based on the ideXlab platform.
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Growth of Rhodospirillum rubrum on synthesis Gas: Conversion of CO to H2 and poly‐β‐hydroxyalkanoate
Biotechnology and bioengineering, 2007Co-Authors: Young S., J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
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Growth of rhodospirillum rubrum on synthesis Gas conversion of co to h2 and poly β hydroxyalkanoate
Biotechnology and Bioengineering, 2007Co-Authors: J. Smeenk, Karl M. Broer, Clint J. Kisting, Robert C. Brown, Theodore J. Heindel, Thomas A. Bobik, Alan A. DispiritoAbstract:To examine the potential use of synthesis Gas as a carbon and enerGy source in fermentation processes, Rhodospirillum rubrum was cultured on synthesis Gas Generated from discarded seed corn. The Growth rates, Growth and poly-β-hydroxyalkanoates (PHA) yields, and CO oxidation/H2 evolution rates were evaluated in comparison to the rates observed with an artificial synthesis Gas mixture. DependinG on the Gas conditioninG system used, synthesis Gas either stimulated or inhibited CO-oxidation rates compared to the observations with the artificial synthesis Gas mixture. Inhibitory and stimulatory compounds in synthesis Gas could be removed by the addition of activated charcoal, char-tar, or char-ash filters (char, tar, and ash are Gasification residues). In batch fermentations, approximately 1.4 mol CO was oxidized per day per G Cell protein with the production of 0.75 mol H2 and 340 mG PHA per day per G Cell protein. The PHA produced from R. rubrum Grown on synthesis Gas was composed of 86% β-hydroxybutyrate and 14% β-hydroxyvalerate. Mass transfer of CO into the liquid phase was determined as the rate-limitinG step in the fermentation. Biotechnol. BioenG. 2007;97: 279–286. © 2006 Wiley Periodicals, Inc.
