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Physiological responses to mixing in large scale bioreactors.

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Physiological responses to mixing in large scale bioreactors. / Enfors, S O; Jahic, M; Rozkov, A; Xu, B; Hecker, M; Jürgen, B; Krüger, E; Schweder, T; Hamer, G; O'Beirne, D; Noisommit-Rizzi, N; Reuss, M; Boone, L; Hewitt, C; McFarlane, C; Nienow, A; Kovacs, T; Trägårdh, C; Fuchs, L; Revstedt, J; Friberg, P C; Hjertager, B; Blomsten, G; Skogman, H; Hjort, S; Hoeks, F; Lin, Hongying; Neubauer, P; van der Lans, R; Luyben, K; Vrabel, P; Manelius, A.

in: J BIOTECHNOL, Jahrgang 85, Nr. 2, 2, 2001, S. 175-185.

Publikationen: SCORING: Beitrag in Fachzeitschrift/ZeitungSCORING: ZeitschriftenaufsatzForschungBegutachtung

Harvard

Enfors, SO, Jahic, M, Rozkov, A, Xu, B, Hecker, M, Jürgen, B, Krüger, E, Schweder, T, Hamer, G, O'Beirne, D, Noisommit-Rizzi, N, Reuss, M, Boone, L, Hewitt, C, McFarlane, C, Nienow, A, Kovacs, T, Trägårdh, C, Fuchs, L, Revstedt, J, Friberg, PC, Hjertager, B, Blomsten, G, Skogman, H, Hjort, S, Hoeks, F, Lin, H, Neubauer, P, van der Lans, R, Luyben, K, Vrabel, P & Manelius, A 2001, 'Physiological responses to mixing in large scale bioreactors.', J BIOTECHNOL, Jg. 85, Nr. 2, 2, S. 175-185. <http://www.ncbi.nlm.nih.gov/pubmed/11165362?dopt=Citation>

APA

Enfors, S. O., Jahic, M., Rozkov, A., Xu, B., Hecker, M., Jürgen, B., Krüger, E., Schweder, T., Hamer, G., O'Beirne, D., Noisommit-Rizzi, N., Reuss, M., Boone, L., Hewitt, C., McFarlane, C., Nienow, A., Kovacs, T., Trägårdh, C., Fuchs, L., ... Manelius, A. (2001). Physiological responses to mixing in large scale bioreactors. J BIOTECHNOL, 85(2), 175-185. [2]. http://www.ncbi.nlm.nih.gov/pubmed/11165362?dopt=Citation

Vancouver

Enfors SO, Jahic M, Rozkov A, Xu B, Hecker M, Jürgen B et al. Physiological responses to mixing in large scale bioreactors. J BIOTECHNOL. 2001;85(2):175-185. 2.

Bibtex

@article{eb1d9bb856e24945978838ff161f3095,
title = "Physiological responses to mixing in large scale bioreactors.",
abstract = "Escherichia coli fed-batch cultivations at 22 m3 scale were compared to corresponding laboratory scale processes and cultivations using a scale-down reactor furnished with a high-glucose concentration zone to mimic the conditions in a feed zone of the large bioreactor. Formate accumulated in the large reactor, indicating the existence of oxygen limitation zones. It is suggested that the reduced biomass yield at large scale partly is due to repeated production/re-assimilation of acetate from overflow metabolism and mixed acid fermentation products due to local moving zones with oxygen limitation. The conditions that generated mixed-acid fermentation in the scale-down reactor also induced a number of stress responses, monitored by analysis of mRNA of selected stress induced genes. The stress responses were relaxed when the cells returned to the substrate limited and oxygen sufficient compartment of the reactor. Corresponding analysis in the large reactor showed that the concentration of mRNA of four stress induced genes was lowest at the sampling port most distant from the feed zone. It is assumed that repeated induction/relaxation of stress responses in a large bioreactor may contribute to altered physiological properties of the cells grown in large-scale bioreactor. Flow cytometric analysis revealed reduced damage with respect to cytoplasmic membrane potential and integrity in cells grown in the dynamic environments of the large scale reactor and the scale-down reactor.",
author = "Enfors, {S O} and M Jahic and A Rozkov and B Xu and M Hecker and B J{\"u}rgen and E Kr{\"u}ger and T Schweder and G Hamer and D O'Beirne and N Noisommit-Rizzi and M Reuss and L Boone and C Hewitt and C McFarlane and A Nienow and T Kovacs and C Tr{\"a}g{\aa}rdh and L Fuchs and J Revstedt and Friberg, {P C} and B Hjertager and G Blomsten and H Skogman and S Hjort and F Hoeks and Hongying Lin and P Neubauer and {van der Lans}, R and K Luyben and P Vrabel and A Manelius",
year = "2001",
language = "Deutsch",
volume = "85",
pages = "175--185",
journal = "J BIOTECHNOL",
issn = "0168-1656",
publisher = "Elsevier",
number = "2",

}

RIS

TY - JOUR

T1 - Physiological responses to mixing in large scale bioreactors.

AU - Enfors, S O

AU - Jahic, M

AU - Rozkov, A

AU - Xu, B

AU - Hecker, M

AU - Jürgen, B

AU - Krüger, E

AU - Schweder, T

AU - Hamer, G

AU - O'Beirne, D

AU - Noisommit-Rizzi, N

AU - Reuss, M

AU - Boone, L

AU - Hewitt, C

AU - McFarlane, C

AU - Nienow, A

AU - Kovacs, T

AU - Trägårdh, C

AU - Fuchs, L

AU - Revstedt, J

AU - Friberg, P C

AU - Hjertager, B

AU - Blomsten, G

AU - Skogman, H

AU - Hjort, S

AU - Hoeks, F

AU - Lin, Hongying

AU - Neubauer, P

AU - van der Lans, R

AU - Luyben, K

AU - Vrabel, P

AU - Manelius, A

PY - 2001

Y1 - 2001

N2 - Escherichia coli fed-batch cultivations at 22 m3 scale were compared to corresponding laboratory scale processes and cultivations using a scale-down reactor furnished with a high-glucose concentration zone to mimic the conditions in a feed zone of the large bioreactor. Formate accumulated in the large reactor, indicating the existence of oxygen limitation zones. It is suggested that the reduced biomass yield at large scale partly is due to repeated production/re-assimilation of acetate from overflow metabolism and mixed acid fermentation products due to local moving zones with oxygen limitation. The conditions that generated mixed-acid fermentation in the scale-down reactor also induced a number of stress responses, monitored by analysis of mRNA of selected stress induced genes. The stress responses were relaxed when the cells returned to the substrate limited and oxygen sufficient compartment of the reactor. Corresponding analysis in the large reactor showed that the concentration of mRNA of four stress induced genes was lowest at the sampling port most distant from the feed zone. It is assumed that repeated induction/relaxation of stress responses in a large bioreactor may contribute to altered physiological properties of the cells grown in large-scale bioreactor. Flow cytometric analysis revealed reduced damage with respect to cytoplasmic membrane potential and integrity in cells grown in the dynamic environments of the large scale reactor and the scale-down reactor.

AB - Escherichia coli fed-batch cultivations at 22 m3 scale were compared to corresponding laboratory scale processes and cultivations using a scale-down reactor furnished with a high-glucose concentration zone to mimic the conditions in a feed zone of the large bioreactor. Formate accumulated in the large reactor, indicating the existence of oxygen limitation zones. It is suggested that the reduced biomass yield at large scale partly is due to repeated production/re-assimilation of acetate from overflow metabolism and mixed acid fermentation products due to local moving zones with oxygen limitation. The conditions that generated mixed-acid fermentation in the scale-down reactor also induced a number of stress responses, monitored by analysis of mRNA of selected stress induced genes. The stress responses were relaxed when the cells returned to the substrate limited and oxygen sufficient compartment of the reactor. Corresponding analysis in the large reactor showed that the concentration of mRNA of four stress induced genes was lowest at the sampling port most distant from the feed zone. It is assumed that repeated induction/relaxation of stress responses in a large bioreactor may contribute to altered physiological properties of the cells grown in large-scale bioreactor. Flow cytometric analysis revealed reduced damage with respect to cytoplasmic membrane potential and integrity in cells grown in the dynamic environments of the large scale reactor and the scale-down reactor.

M3 - SCORING: Zeitschriftenaufsatz

VL - 85

SP - 175

EP - 185

JO - J BIOTECHNOL

JF - J BIOTECHNOL

SN - 0168-1656

IS - 2

M1 - 2

ER -