Continuous production of 4-ethylguaiacol by immobilized cells of salt-tolerant Candida versatilis in an airlift reactor

The effects of pH, temperature, aeration, and residence time on the continuous production of 4-ethyl-guaiacol (4-EG), which is one of the characteristic aroma components in soy sauce, by immobilized cells of the salt-tolerant yeast Candida versatilis were investigated using an airlift reactor. The optimum pH and temperature were about 4.0 and 30–33°C, respectively. The amount of 4-EG in the liquid was constant even during alterations of nitrogen/air ratio in the supplied gas. A large amount of 4-EG (over 20 ppm) was produced at a residence time from 5 to 28 h and 1–3 ppm of 4-EG, which was the optimum concentration in conventional soy souce, was produced at a shorter residence time of 0.5 h. The 4-EG production by immobilized C. versatilis cells using the airlift reactor was stable for 40 d. It was found that the immobilized cell method was effective for the production of 4-EG by C. versatilis cells.     

Process and technoeconomics of ethanol production by immobilized cells

Summary A two-stage fermentation process has been developed for continuous ethanol production by immobilized cells of Zymomonas mobilis. About 90–92 kg/m³ ethanol was produced after 4 h of residence time. Entrapped cells of Zymomonas mobilis have a capability to convert glucose to ethanol at 93% of the theoretical yield. The immobilized cell system has functioned for several weeks, and experience indicates that the carrageenan gel apparently facilitates easy diffusion of glucose and ethanol.The simplicity and the high productivity of the plug-flow reactor employing immobilized cells makes it economically attrative. An evaluation of process economics of an immobilized cell system indicates that at least 4 c/l of ethanol can be saved using the immobilized cell system rather than the conventional batch system. The high productivity achieved in the immobilized cell reactor results in the requirement for only small reactor vessels indicating low capital cost. Consequently, by switching from batch to immobilized processing, the fixed capital investment is substantially reduced, thus increasing the profitability of ethanol production by fermentation.     

Ethanol production from sulphuric acid wood hydrolysate ofPinus radiata using free and immobilized cells ofPichia stipitis

Summary Ethanol was produced by a strain ofPichia stipitis adapted to an inhibitory acid wood hydrolysate ofPinus radiata. The best ethanol productivity for batch cultures was 0.21 g/l h at 0.7% ethanol. Varying culture conditions increased ethanol concentration to 0.76%, however the productivity decreased to 0.18 g/l h. A decrease in ethanol concentration in the culture fluid was noted late in the batch which suggested ethanol catabolism. Values of kinetic parameters (K _m,K _s, _max, andV _max) were evaluated for this system. The use of calcium alginate immobilized cells in a continuous-flow stirred tank reactor lead to enhanced fermentative performance, namely a maximum productivity of 0.27 g/l h and 1.13% ethanol yield. The immobilized cells in continuous flow reactors represent an attractive option for fermenting sugars released by sulphuric acid hydrolysis ofP. radiata wood.     

Citric acid production by Aspergillus niger immobilized on polyurethane foam

Summary Citric acid was produced using Aspergillus niger immobilized on polyurethane foam in a bubble column reactor. Most of the adsorbed cells remained on the support and, as a result, high oxygen tension was maintained during the reactor operation. However, uncontrolled growth of the pellets made continuous reactor operation difficult. The citric acid productivity obtained from 15 vol.% foam particles containing immobilized cells was 0.135 g/l per hour. This productivity of immobilized cells was almost the same as that of free cells. The oxygen level dropped to half saturation in 5 days in the immobilized cell culture in contrast to 2 days in the free cell culture.     

A New Process for Soy Sauce Fermentation by Immobilized Yeasts

Using bioreactors with yeasts, Zygosaccharomyces rouxii that undergoes ethanol fermentation and produces 2-phenyl ethanol, and Candida versatilis that produces 4-ethyl guaiacol, adsorbed-immobilized on a ceramic carrier, the total time required for production of soy sauce was shortened to 8 days without affecting the product’s quality.     

Fumaric acid production from xylose by immobilized Rhizopus arrhizus cells

Summary The production of fumaric acid by immobilized Rhizopus arrhizus TKK 204-1-1a mycelium was optimized in batch fermentations using statistical experimental design and empiric modelling. The maximum fumaric acid concentration was obtained at a xylose concentration of about 6% and a carbon:nitrogen ratio of about 160. In repeated batch fermentations with immobilized cells the highest volumetric productivity of fumaric acid reached was 87 mg/l per hour when the initial xylose concentration was 10%, the C:N ratio 160 and the residence time 1.75 days. The maximum product concentration was 16.4 g/l when the initial xylose concentration was 10%, the C:N ratio 160 and the residence time 10.25 days. The maximum yield from initial xylose (6.47%) was 23.7% with a product concentration of 15.3 g/l and volumetric productivity of 71 mg/l per hour at a residence time of 9 days and a C:N ratio of 188.3. Immobilization could increase the fumaric acid concentration to a level 3.4 times higher than that produced by free cells.     

A comparison between the fermentative activities of free and Ca-alginate-entrapped cells of saccharomyces cerevisiae

The continuous ethanol production by free and Ca-alginate-entrapped cells of the yeast Saccharomyces cer. IBT H 191 was investigated in a membrane reactor and in a CSTR, respectively. An empiric productivity model for free-cell fermentation was found to be valid for immobilized cells if no external diffusion resistance existed within the reactor. In such a case the fermentative power of the immobilized cells was identical with this one of the free cells. A change of the ethanol-tolerance behaviour of the cells as a result of the cell-immobilization did not occur.     

Genome shuffling of <Emphasis Type="Italic">Hansenula anomala</Emphasis> to improve flavour formation of soy sauce

Genome shuffling of mutagenized Hansenula anomala was used to improve soy-sauce flavour by enhancing its salt-tolerance, because the concentration of salt was about 17% in high-salt liquid fermentation of soy sauce. A mutant strain H3-8, with stronger resistance to salt, was selected and screened after three rounds of genome shuffling. It was found that H3-8 could grow in YPD media containing a high salt content and within a wide range of pH. In high-salt liquid fermentation, the soy-sauce flavour components produced by H3-8 were distinctly improved compared with the control strains Zygosaccharomyces rouxii and Torulopsis versatilis. Notably, hydroxyethylmethylfuranone produced by H3-8 was 6.3 times as high as that formed by Z. rouxii. Ethyl acetate synthesized by H3-8 was 734 times higher than that yielded by T. versatilis. Another important aroma component, 4-ethylguaiacol was increased by up to 10.84% compared with T. versatilis.     

Ribonuclease production by free and immobilizedAspergillus clavatus cells

Several fungal strains ofAspergillus andPenicillium were immobilized by cryopolymerization in polyvinyl alcohol cryogel beads.Aspergillus clavatus was the best producer of extracellular ribonuclease. Enzyme productivity and growth of free and immobilized cells in shake flasks and agitated bioreactor were studied. Ribonuclease production and growth behaviour depended on concentrations of glucose, peptone and soybean in the culture medium. Enzyme production was influenced by agitation and aeration intensity. In repeated batch, shake-flask cultures, the immobilized cells showed 2 to 3.5 times higher enzyme activity than free cells. The optimal conditions in a bioreactor were at 150 rev/min agitation speed and 0.5 vol/vol.min aeration. Enzyme productivity of immobilized cells (237 units/g dry mycelium.h) was 2.1 times higher than the productivity of free cells in a bioreactor, and 2.3 times higher than that of a shake-flask culture.R.J. Manolov is with the Institute of Microbiology, Department of Enzymes, Bulgarian Academy of Sciences, Georgy Bonchev Street 26, 1113 Sofia, Bulgaria.     

Ethanol production by immobilized whole cells ofZymomonas mobilis in a continuous flow expanded bed bioreactor and a continuous flow stirred tank bioreactor

Continuous ethanol fermentation by immobilized whole cells ofZymomonas mobilis was investigated in an expanded bed bioreactor and in a continuous stirred tank reactor at glucose concentrations of 100, 150 and 200 g L^–1. The effect of different dilution rates on ethanol production by immobilized whole cells ofZymomonas mobilis was studied in both reactors. The maximum ethanol productivity attained was 21 g L^–1 h^–1 at a dilution rate of 0.36 h^–1 with 150 g glucose L^–1 in the continuous expanded bed bioreactor. The conversion of glucose to ethanol was independent of the glucose concentration in both reactors.     

Semicontinuous production of red pigment by immobilized cells of<Emphasis Type="Italic">Bacillus</Emphasis> sp. BH-99 using column bioreactor

The semicontinuous production of red pigment by immobilized cells ofBacillus sp. BH-99 was investigated in comparison with free cells. The red pigment produced highest productivity under the conditions of aeration of 0.2 mL/min and 2 mm diameter of gel beads by using 3.0% sodium alginate. Semicontinuous production by immobilized cells showed the highest productivity with replacement of fresh production medium in every 72 h for fourth fermentation cycle following the conditions of red pigment productivity.     

Production of alkaline protease with immobilized cells of bacillus subtilis PE-11 in various matrices by entrapment technique

The purpose of this investigation was to study the effect ofBacillus subtilis PE-11 cells immobilized in various matrices, such as calcium alginate, k-Carrageenan, ployacrylamide, agar-agar, and gelatin, for the production of alkaline protease. Calcium alginate was found to be an effective and suitable matrix for higher alkaline protease productivity compared to the other matrices studied. All the matrices were selected for repeated batch fermentation. The average specific volumetric productivity with calcium alginate was 15.11 U/mL/hour, which was 79.03% higher production over the conventional free-cell fermentation. Similarly, the specific volumetric productivity by repeated batch fermentation was 13.68 U/mL/hour with k-Carrageenan, 12.44 U/mL/hour with agar-agar, 11.71 U/mL/hour with polyacrylamide, and 10.32 U/mL/hour with gelatin. In the repeated batch fermentations of the shake flasks, an optimum level of enzyme was maintained for 9 days using calcium alginate immobilized cells. From the results, it is concluded that the immobilized cells ofB subtilis PE-11 in calcium alginate are more efficient for the production of alkaline protease with repeated batch fermentation. The alginate immobilized cells ofB subtilis PE-11 can be proposed as an effective biocatalyst for repeated usage for maximum production of alkaline protease. Published: October 21, 2005     

Combined alcoholic fermentation of D-xylose and D-glucose by four selected microbial strains: Process considerations in relation to ethanol tolerance

Summary As components of combined fermentation of both glucose and xylose to ethanol by separated or coculture processes, the effects of initial sugar concentrations on the fermentative performances ofPichia stipitis Y7124,Candida shehatae ATCC 22984,Saccharomyces cerevisiae CBS1200 andZymomonas mobilis ATCC10988 were investigated. From the characteristics of sugar and produced ethanol tolerances the most suitable microorganisms for the achievement of glucose and xylose fermentations have been selected with respect to different fermentation schemes.Nomenclature Tf fermentation time (hours) - Ef ethanol concentration (g/l) - Y_P/S ethanol yield (g of ethanol produced/g of sugar used) - qp average specific productivity of ethanol (g ethanol/g of cells per hour) - max maximum specific growth rate (h^–1)     

Continuous production of isomalto-oligosaccharides from maltose syrup by immobilized cells of permeabilizedAureobasidium pullulans

Continuous production of isomalto-oligosaccharides from maltose syrup by the permeabilized cells ofAureobasidium pullulans immobilized into calcium alginate gel was studied using a column reactor. The immobilized cell column maintained its full activity over 45 days when the reactor was operated at a velocity of 0.1 h^–1 at 50°C using 60%(w/v) maltose syrup as a substrate, and the maximum productivity achieved was around 60 g/1h.     

Alcoholic fermentation of D-xylose by immobilizedPichia stipitis yeast

Summary Pichia stipitis NRRL Y-7124 yeast cells were for the first time immobilized both in agar gel beads and on fine nylon net for ethanol fermentation on D-xylose, in order to investigate the possibility of using the biocatalyst for improved utilization of the biomass pentose fraction. With free cells the initial xylose level affected little ethanol production, with a maximum of 22 g/l ethanol obtained in 5 days on 5% and of 40 g/l in 8 days on 10% xylose, and an average volumetric productivity of about 0.22 g/lh. The maximum ethanol concentration of 19.5% on 5% xylose with the nylon net attached cells in a continuous packed-bed column reactor was obtained with 35 h residence time. The volumetric productivities of 0.56 g/lh at 19.5 g/l ethanol and 1.0 g/lh at 15.0 g/l ethanol were markedly higher than those obtained with free cells. The stability of the immobilized biocatalyst was excellent. The same reactor could be used for at least 80 days without significant activity loss.     

Microencapsulation of recombinant Saccharomyces cerevisiae cells with invertase activity in liquid-core alginate capsules

As a means of integrating cell growth and immobilization, recombinant Saccharomyces cerevisiae cells with invertase activity were immobilized in liquid-core alginate capsules and cultured to a high density. S. cerevisiae cells of SEY 2102 (MAT alpha ura3-52 leu2-3, 112 his4-519) harboring plasmid pRB58 with the SUC2 gene coding for invertase were grown to 83 g/L of liquid-core volume inside the capsule on a dry weight basis. The cloned invertase was expressed well in the immobilized cells with slightly higher activity than the free cells in a batch culture. Invertase in the immobilized cells showed slightly more improved thermal stability than in the free cells. Storage in a Na-acetate buffer at 4 degrees C and 10 degrees C for 1 month resulted in 7% and 8% loss in activity, respectively. The sucrose hydrolysis reaction was stably maintained for 25 repeated batches for 7 days at 30 degrees C. Continuous hydrolysis of 0.3 M sucrose was carried out in a packed bed reactor with a conversion of more than 90% at a maximum productivity of 55.5 g glucose/L per hour for 7 days. In a continuous stirred tank reactor, the maximum productivity of 80.8 g glucose/L per hour was achieved at a conversion of 59.1% using 1.0 M sucrose solution, and 0.5 M sucrose solution was hydrolyzed for 1 week with a 95% conversion at a productivity of 48.8 g/L per hour. (c) 1996 John Wiley & Sons, Inc.     

Ethanol production from concentrated food waste hydrolysates with yeast cells immobilized on corn stalk

The aim of the present study was to examine ethanol production from concentrated food waste hydrolysates using whole cells of S. cerevisiae immobilized on corn stalks. In order to improve cell immobilization efficiency, biological modification of the carrier was carried out by cellulase hydrolysis. The results show that proper modification of the carrier with cellulase hydrolysis was suitable for cell immobilization. The mechanism proposed, cellulase hydrolysis, not only increased the immobilized cell concentration, but also disrupted the sleek surface to become rough and porous, which enhanced ethanol production. In batch fermentation with an initial reducing sugar concentration of 202.64 ± 1.86 g/l, an optimal ethanol concentration of 87.91 ± 1.98 g/l was obtained using a modified corn stalk-immobilized cell system. The ethanol concentration produced by the immobilized cells was 6.9% higher than that produced by the free cells. Ethanol production in the 14th cycle repeated batch fermentation demonstrated the enhanced stability of the immobilized yeast cells. Under continuous fermentation in an immobilized cell reactor, the maximum ethanol concentration of 84.85 g/l, and the highest ethanol yield of 0.43 g/g (of reducing sugar) were achieved at hydraulic retention time (HRT) of 3.10 h, whereas the maximum volumetric ethanol productivity of 43.54 g/l/h was observed at a HRT of 1.55 h.     

Continuous ethanol production from pineapple cannery waste using immobilized yeast cells

The cells of Saccharomyces cerevisiae ATCC 24553, were immobilized in k-carrageenan and packed in a tapered glass column reactor for ethanol production from pineapple cannery waste at temperature 30 degrees C and pH 4.5. The maximum productivity was 42.8 g ethanol 1(-1) h(-1) at a dilution rate of 1.5 h(-1). The volumetric ethanol productivity of the immobilized cells was ca. 11.5 times higher than the free cells. The immobilized cell reactor was operated over a period of 87 days at a dilution rate of 1.0 h(-1), without any loss in the immobilized cell activity. The maximum specific ethanol productivity and specific sugar uptake rate of the immobilized cells were 1.2 g ethanol g(-1) dry wt. cell h(-1) and 2.6 g sugar g(-1) dry wt. cell h(-1), respectively, at a dilution rate of 1.5 h(-1).     

Improved production of viable cells of the salt-tolerant yeast Zygosaccharomyces rouxii by continuous culture

Summary A continuous culture system of the salt-tolerant yeast Zygosaccharomyces rouxii (soy yeast) was investigated in order to obtain high production efficiency of viable cells. The optimum pH and C/N ratio of the feed medium for cell production were about 5.0 and 16–20, respectively. About a fivefold increase in viable cell number and cell productivity (viable cell number per litre per hour) were obtained in glucose-limited culture at a dilution rate (D) of 0.06 h^–1 as compared with batch culture. However, the fermentative activity of the cells from glucose-limited culture was significantly lower than those from batch and dissolved-oxygen (DO)-limited cultures, and the former cells showed lower specific activity of glycolytic enzymes. On the other hand, at the boundary conditions between glucose and DO limitation almost the same cell productivity and higher fermentative activity of the cell were obtained as compared with glucose-limited conditions. The cultivation continued for about 60 days without any problems even if the D was altered. It was found that the continuous cultivation method was suitable for industrial production of viable cells of soy yeasts. Offprint requests to: T. Hamada     

Production of L-lysine by free and PVA-cryogel immobilizedCorynebacterium glutamicum cells

Summary Free and immobilized cells ofC. glutamicum were analyzed for production of L-lysine. Non-growing free cells as well as immobilized ones produced higher levels of lysine than growing free cells, when cultured for 24 h in a medium containing 80 g/L glucose as a carbon source. The effect of initial biomass and yeast extract concentrations was investigated in order to improve lysine production.