G. Nebe-von Caron scite author profile

Multiparameter flow cytometric techniques developed in our laboratories have been used for the "at-line" study of fed-batch bacterial fermentations. These fermentations were done at two scales, production (20 m(3)) and bench (5 x 10(-3) m(3)). In addition, at the bench scale, experiments were undertaken where the difficulty of achieving good mixing (broth homogeneity), similar to that found at the production scale, was simulated by using a two-compartment model. Flow cytometric analysis of cells in broth samples, based on a dual-staining protocol, has revealed, for the first time, that a progressive change in cell physiological state generally occurs throughout the course of such fermentations. The technique has demonstrated that a changing microenvironment with respect to substrate concentration (glucose and dissolved oxygen tension [DOT]) has a profound effect on cell physiology and hence on viable biomass yield. The relatively poorly mixed conditions in the large-scale fermentor were found to lead to a low biomass yield, but, surprisingly, were associated with a high cell viability (with respect to cytoplasmic membrane permeability) throughout the fermentation. The small-scale fermentation that most clearly mimicked the large-scale heterogeneity (i.e., a region of high glucose concentration and low DOT analogous to a feed zone) gave similar results. On the other hand, the small-scale well-mixed fermentation gave the highest biomass yield, but again, surprisingly, the lowest cell viability. The scaled-down simulations with high DOT throughout and locally low or high glucose gave biomass and viabilities between. Reasons for these results are examined in terms of environmental stress associated with an ever-increasing glucose limitation in the well-mixed case. On the other hand, at the large scale, and to differing degrees in scale-down simulations, cells periodically encounter regions of relatively higher glucose concentration.

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Determination of the intracellular pH (pHi) of growing cells of Saccharomyces cerevisiae: the effect of reduced-expression of the membrane H+-ATPase

Bracey

Holyoak

Caron

et al. 1998

Journal of Microbiological Methods

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Use of multi-staining flow cytometry to characterise the physiological state ofEscherichia coli W3110 in high cell density fed-batch cultures

Hewitt

Caron

Nienow

et al. 1999

Biotechnol. Bioeng.

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High cell density fed‐batch fermentations of Escherichia coli W3110 have been carried out at specific growth rates of less than 0.3 h−1, to investigate the effect of glucose limitation on the physiological state of individual cells. After an initial exponential batch phase, the feed rate was held constant and a final dry cell weight of approximately 50 g per litre was achieved. The fermentations were monitored by mass spectrometry whilst measurements of pH, DOC, CFU/mL, TCN, OD500nm and residual glucose concentrations were made. Satisfactory and reproducible results were obtained. Flow cytometric analysis of cells in broth samples, based on either of two multi‐staining protocols, revealed a progressive change in cell physiological state throughout the course of the fermentations. From these measurements it was concluded that the loss in reproductive viability towards the end of the fed‐batch process is due to cell death and not due to the formation of a “viable but nonculturable state” as had previously been reported. Since the presence of a high proportion of dead or dying cells at any time during a fermentation has a detrimental effect on the synthesis of any desired product it is proposed that an on‐line flow cytometric analysis and control strategy could be used as a means of increasing overall process efficiency. © 1999 John Wiley & Sons, Inc. Biotechnol Bioeng 63: 705–711, 1999.

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Stressed Salmonella are exposed to reactive oxygen species from two independent sources during recovery in conventional culture media

Stephens¹,

Druggan²,

Caron

2000

International Journal of Food Microbiology

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G. Nebe-von Caron

The use of multi-parameter flow cytometry to compare the physiological response of Escherichia coli W3110 to glucose limitation during batch, fed-batch and continuous culture cultivations

Studies related to the scale‐up of high‐cell‐density E. coli fed‐batch fermentations using multiparameter flow cytometry: Effect of a changing microenvironment with respect to glucose and dissolved oxygen concentration

Determination of the intracellular pH (pHi) of growing cells of Saccharomyces cerevisiae: the effect of reduced-expression of the membrane H+-ATPase

Use of multi-staining flow cytometry to characterise the physiological state ofEscherichia coli W3110 in high cell density fed-batch cultures

Stressed Salmonella are exposed to reactive oxygen species from two independent sources during recovery in conventional culture media

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