Optimization of the microbial synthesis of dihydroxyacetone in a semi-continuous repeated-fed-batch process by in situ immobilization of Gluconobacter oxydans

The effect of in situ immobilization of Gluconobacter oxydans on a novel carrier material in a repeated-fed-batch operated packed-bed bubble-column bioreactor for the production of the fine chemical dihydroxyacetone was investigated experimentally. The carrier material were biocompatible, durable, coated Ralu-rings. The coating was a porous silicone matrix with satisfactory wetting characteristics. Settling of cells was relatively rapid. The cells were protected from abrasion caused by shear forces. A sufficiently high oxygen supply rate to the immobilized cells was provided due to the high oxygen permeability of the silicone matrix. The immobilized biomass was estimated to be about 65% of the total biomass contained in the bioreactor after 18 days of operation. The observed space-time yield was approx. 76% higher compared to a similar process which was performed without an optimized fermentation medium. Compared to previous experiments with a trickle-bed bioreactor, the space-time yield was approx. 3.7 times higher. A typical time course of the immobilization process was observed: after an induction phase, a transition phase followed which later on gave way to a nearly linear accumulation phase. A stationary phase with regard to the amount of immobilized active cells, however, was not reached. Hence, a higher bioreactor performance than observed could be expected at longer operation times. (c) 2006 Elsevier Ltd. All rights reserved.