Abstract
The influence of several polymeric additives on specific glucose uptake rate of flocs of a S. cerevisiae strain — S. cerevisiae NRRLY 265 was studied. A special continuous membrane microreactor was used to measure glucose uptake on the presence of calcium and of the tested additives — two cationic polymers — bis(polyoxyethylene-bis(amine)) 20,000 and BPA 1,000 and one anionic polymer — Magna Floc LT25.
An increase on glucose uptake rate was always observed when comparing with calcium bound flocs. For bis(polyoxyethylene-bis(amine)) 20,000 the increase was only 19% but for BPA 1,000 a value of more than 50% was observed. For Magna Floc LT25 a two fold increase was measured.
The determination of floc size and porosity in the presence of the additives indicated that, on the basis of these parameters, it was not possible to explain the observed glucose uptake rates. The floc porosites in additive bound flocs were similar and 10% larger than for calcium bound flocs and glucose uptake rate was larger for the largest flocs — Magna Floc LT25 bound flocs were the largest followed by BPA 1,000, bis(polyoxyethylene-bis(amine)) 20,000 and calcium bound flocs. These values disagree with what should be expected in diffusion controlled processes.
The calculation of intercellular floc distance indicated that polymeric additives act on the reduction of diffusional limitations by increasing the available flux area for glucose inside the flocs. By analysing different kinds of packings, it was also observed that the packing arrangement for yeast cells in flocs is close to the cubic packing. The simulation of this arrangement for the obtained floc sizes confirmed that the 10% increase in floc porosity is sufficient to explain the increase in the available flux area.
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Lima, N., Teixeira, J.A. & Mota, M. Enhancement of metabolic rates of yeast flocculent cells through the use of polymeric additives. Bioprocess Engineering 7, 343–348 (1992). https://doi.org/10.1007/BF00369489
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DOI: https://doi.org/10.1007/BF00369489