Dissertationen zum Thema „Fermentation – Productivité“
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Ozcelik, Hayriye. „Productivity Analyses In Fermentations With Three Different Biolarvacides“. Master's thesis, METU, 2004. http://etd.lib.metu.edu.tr/upload/3/12604988/index.pdf.
Der volle Inhalt der QuelleLacerda, Filho Armando Marsden. „Fermentation systems for enhancement of ethanol productivity in Saccharomyces cerevisiae at elevated temperatures“. Thesis, University of St Andrews, 1996. http://hdl.handle.net/10023/14371.
Der volle Inhalt der QuelleLaouali, Mahaman Sani. „Mise au point d'une filière complète de traitement des eaux usées urbaines de régions tropicales : digesteur à biomasse fixée, lagunages à Microphytes et à Macrophytes, production piscicole“. Montpellier 2, 1990. http://www.theses.fr/1990MON20141.
Der volle Inhalt der QuelleGomes, Elenice Mendes Silva. „Influência das concentrações de açúcares nos mostos sobre o desempenho da fermentação etanólica conduzida em batelada alimentada com vazão variável de alimentação“. Universidade Federal de Alagoas, 2011. http://www.repositorio.ufal.br/handle/riufal/1202.
Der volle Inhalt der QuelleFundação de Amparo a Pesquisa do Estado de Alagoas
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior
Este estudo objetivou avaliar a influência das concentrações de açúcares nos mostos, sobre o desempenho da fermentação etanólica conduzida em batelada alimentada com vazão variável de alimentação, para a definição das melhores concentrações de ART nos mostos (de caldo, de melaço e misto) que conduzam a melhores eficiências de fermentação e produtividade em etanol. Na preparação do mosto misto foram utilizadas as seguintes proporções (20% melaço + 80% caldo, 40% melaço + 60% caldo, 50% melaço + 50% caldo, 60% melaço + 40% caldo, 80% melaço + 20% caldo). O perfil de alimentação foi decrescente, variando-se a vazão de 0,75 a 0,25 L.h-1, com tempo de enchimento do fermentador de 3 horas para todos os ensaios, variando-se de 30 em 30 minutos a vazão de alimentação de mosto, em fermentador de 4L de volume de trabalho (3 litros de mosto e 1 litro de inoculo), avaliando-se diferentes concentrações de ART nos 3 tipos de mosto estudados. Foram avaliados parâmetros de desempenho, como eficiências fermentativa e de processo e produtividade em etanol. Nos mostos foram quantificados pH, acidez sulfúrica, Brix e ART. No meio fermentado (vinho), pH, acidez, Açúcares Residuais e teor de etanol e quantidade de células. O perfil cinético foi definido, quantificando-se as concentrações de células, substrato e etanol (em intervalos de 1 hora). Os valores indicados neste estudo, como ponto de partida para utilização industrial, são Brix de 16 a 18 (ART 114,25 a 125,86 g/L), de 14 a 18 °Brix (ART de 112,90 a 141,24 g/L) e próximo de 16 °Brix (ART de 113,68 g/L a 123,30), respectivamente para mostos de melaço, caldo e misto (caldo + melaço). As eficiências de fermentação foram: 77,17 a 90,30%, para mosto de caldo, 74,4 a 86,51% para mosto misto e 61,84 a 84,06 para mosto de melaço. As produtividades obtidas foram 6,85 a 8,21g/L.h, para mosto de caldo, 5,90 a 7,77g/L.h para mosto misto e 4,04 a 6,72g/L.h para mosto d melaço. Estas faixas recomendadas servem para subsidiar, como ponto de partida, a condução da fermentação etanólica industrial conduzida em batelada alimentada com vazão variável de alimentação, visto que as condições de condução dos ensaios, assim como as matérias-primas utilizadas na preparação dos mostos, foram semelhantes às utilizadas industrialmente.
Lee, Jungeun. „Sustainable Production of Microbial Lipids from Renewable Biomass: Evaluation of Oleaginous Yeast Cultures for High Yield and Productivity“. Diss., Kansas State University, 2017. http://hdl.handle.net/2097/35300.
Der volle Inhalt der QuelleDepartment of Grain Science and Industry
Praveen V. Vadlani
Microbial lipids derived from oleaginous yeasts are a promising alternative source of edible oils due to the following advantages: no requirement of broad lands; availability of year-round production; and no food versus fuels controversy. Oleaginous yeast has an inherent ability to accumulate lipids inside cells and their lipids are preferable as starting materials in oleo-chemical industries because of their distinct fatty acid composition. Lignocellulosic biomass is a promising substrate to supply carbon sources for oleaginous yeast to produce lipids due to the high content of polysaccharides and their abundancy. Lignocellulosic-based sugar streams, which can be generated via pretreatment and enzymatic hydrolysis, contained diverse monosaccharides and inhibitors. The major objectives of this study were: 1) to develop a novel purification method to generate clean sugar stream using sorghum stalks after acid pretreatment; 2) to optimize fermentation conditions for Trichosporon oleaginosus to achieve high yields and productivity of microbial lipids using lignocellulosic hydrolysates; 3) to investigate the potentials of sorghum stalks and switchgrass as feedstocks for microbial lipid production using oleaginous yeast strains, such as T. oleaginosus, Lipomyces starkeyi, and Cryptococcus albidus; 4) to develop an integrated process of corn bran based-microbial lipids production using T. oleaginosus; and 5) to develop bioconversion process for high yields of lipids from switchgrass using engineered Escherichia coli. In our investigation, major inhibitory compounds of lignocellulosic hydrolysates induced by pretreatment were acetic acid, formic acid, hydroxymethyl furfural (HMF) and furfural. The activated charcoal was effective in removing hydrophobic compounds from sorghum stalk hydrolysates. Resin mixtures containing cationic exchangers and anionic exchangers in 7:3 ratio at pH 2.7 completely removed HMF, acetic acid, and formic acid from sorghum stalk hydrolysates. T. oleaginosus was a robust yeast strain for lipid production. In the nitrogen-limited synthetic media, total 22 g/L of lipid titers were achieved by T. oleaginosus with a lipid content of 76% (w/w). In addition, T. oleaginosus efficiently produced microbial lipids from lignocellulosic biomass hydrolysates. The highest lipid titers of 13 g/L lipids were achieved by T. oleaginosus using sorghum stalk hydrolysates with a lipid content of 60% (w/w). L. starkeyi and C. albidus also successfully produced microbial lipids using lignocellulosic hydrolysate with a lipid content of 40% (w/w). Furthermore, corn bran was a promising feedstock for microbial lipid production. The highest sugar yields of 0.53 g/g were achieved from corn bran at the pretreatment condition of 1% acid and 5% solid loading. Microbial lipids were successfully produced from corn bran hydrolysates by T. oleaginosus with lipid yields of 216 mg/g. Engineered E. coli also effectively produced lipids using switchgrass as feedstocks. E. coli ML103 pXZ18Z produced a total of 3.3 g/L free fatty acids with a yield of 0.23 g/g. The overall yield of free fatty acids was 0.12 g/g of raw switchgrass and it was 51 % of the maximum theoretical yield. This study provided useful strategies for the development of sustainable bioconversion processes for microbial lipids from renewable biomass and demonstrated the economic viability of a lignocellulosic based-biorefinery.
Claret, Carole. „Métabolismes oxydatif et fermentaire du glycérol chez les bactéries : étude physiologique et cinétique de sa conversion en dihydroxyacétone et en 1,3-propanediol“. Toulouse, INSA, 1992. http://www.theses.fr/1992ISAT0034.
Der volle Inhalt der Quelle邱毓明. „Hydrogen-Productivity Comprison of Four types of Anaerobic Fermentation Reactors“. Thesis, 2002. http://ndltd.ncl.edu.tw/handle/35235154753452033928.
Der volle Inhalt der Quelle臺中師範學院
環境教育研究所
90
The conventional anaerobic wastewater treatments are able to deal with various types of organic wastewater and able to recovery biogas, which is mainly methane. Based on the regulation of the Framework Convention On Climate Change, methane is the next item to be put under control due to its greenhouse effect. Hydrogen produced by anaerobic fermentation can be used as an energy source with no greenhouse effect and therefore, become a highly potential technique with a great commercial market. After considering the physiological characteristics and growth condition of anaerobic hydrogenic bacteria, this study has designed 4 typical reactors suitable for anaerobic hydrogenesis , including Sludge recycling reactor, Continuous flow stirred tank reactor (CSTR), Non-mixing conventional reactor, and Plug flow reactor. The hydrogen productivity and wastewater treatment efficiencies of these 4 reactors were compared to evaluate which is the best for anaerobic production of hydrogen. The best operation condition of each reactor was also determined. As the results shown, within the influent COD concentration being 2,000-15,000 mg/L and HRT being 6-24 hrs, the hydrogen productivity is the best with an organic loading of 60 kg-COD/m3×d. Among these 4 reactors, continuous flow stirred tank reactor is the most appropriate for anaerobic fermentation hydrogenesis with a hydrogen productivity of 150 ml/g-CODre and a hydrogen productivity of per unit reactor of 774 L-H2/m3×d(1atm,25℃), followed by non-mixing conventional reactor with a hydrogen productivity of 129 ml/g-CODre and a hydrogen productivity of per unit reactor of 646 L-H2/m3×d(1atm,25℃). Only at a higher organic loading, sludge recycling reactor has a higher efficiency of hydrogen production due to the higher total production with a hydrogen productivity of 74.9 ml/g-CODre(1atm,25℃) and a hydrogen productivity of per unit reactor of 1100 L-H2/m3×d(1atm,25℃). The hydrogen productivity of each reactor was increased with the increase of organic loading and the decrease in HRT, furthermore, the effect of HRT was more significant. At an organic loading of 2 kg-COD/m3×d, all reactors have the best COD removal, ranging from 54.0 to 60.1%, due to the highly methanation at the low organic loading. At an organic loading of 60 kg-COD/m3×d, all reactors have the worst COD removal, ranging from 9.0 to 19.0%. The COD removal of each reactor was decreased with the increase in organic loading and the decrease in HRT. From the observation under the fluorescent microscope and electron microscope, it was found that yellow-orange fluorescence was emitted by a large amount of Clostridium bacteria in biomass while the anaerobic fermentation hydrogenesis was good. However, blue fluorescence, which indicated a highly methanation, was emitted while the anaerobic fermentation hydrogenesis was poor. These results may be helpful in determining the efficiency of anaerobic fermentation hydrogensis .
ChenChang, Chia, und 張嘉真. „Productivity simulation of combined sugar and ethanol production with selective fermentation technology“. Thesis, 2015. http://ndltd.ncl.edu.tw/handle/10409251462345150493.
Der volle Inhalt der Quelle國立成功大學
環境工程學系
103
Selective fermentation realized by invertase-defective yeasts that convert only the reducing sugars in a mixed saccharide (e.g. sugarcane juice) into ethanol is an emerging process technology in sugarcane industry. This technology opens possibilities in stabilization and enhancement of total productivity of sugar and ethanol, as productive and stronger cultivars that have higher content of reducing sugar becomes a potential raw material in sugar mills. To trigger the system-wide innovation of this technology, the changes in stability and enhancement of productivity must be described by changes in cultivars and cropping schedules. Here, a descriptive model developed in this study highlights consequences of introduction of selective fermentation technology considering a given scenario on choice of cultivars and cropping schedules. Moreover, utilizing a prototype database, design of scenarios based on optimization techniques are demonstrated. The results from demonstrative scenario design indicate the potential advantages of selective fermentation technology in combination with a cane cultivar with high yield, high biomass and reducing sugar content on Tanegashima Island of Japan. The study also indicates the new requirement on data from sugarcane cultivation, such as a wider range of growth profiles (stalk weight, composition), growth and harvest observations of perennial ratoon and rate of physical damage by typhoon by varied rationing months. Future directions of study including directions in enhancement of the model and database are discussed.
ZENG, WEN-GI, und 曾文祺. „Effect of fermentation conditions on the growth of recombinant saccharomyces cerevisiae and HBsAg productivity“. Thesis, 1988. http://ndltd.ncl.edu.tw/handle/16356562196326261863.
Der volle Inhalt der QuelleHuang, Chong-ruey, und 黃重睿. „Increasing Productivity of Bio-ethanol by Using Pichia stipitis Fermentation in Continuous Dual-tank“. Thesis, 2011. http://ndltd.ncl.edu.tw/handle/78154135746176485488.
Der volle Inhalt der Quelle大葉大學
生物產業科技學系
99
To avoid grain prices rising and causing inflation, production of the biomass fuel alcohol of the second era is mostly abandoned grain crops, and used the non-grain crops of abounded biomass cellulose or agriculture waste as raw materials. The saccharides that biomass fiber through preprocessing hydrolysis and producing are used by organism methods for fermentation to get alcohol, and the saccharides of the kind of raw materials obtained possess the two classes of five carbon and six carbon. In order to amply use these reducing sugars, developing co-fermentation process is an important topic. The bacteria strains that are able to ferment five carbon saccharides are quite rare in the nature world, and therefore using gene recombination to develop new bacteria strains is an important work. Besides the fermentation rate of the five carbon saccharides is quite slow, and therefore the rising of efficiency is also an important research. This research is according to the earlier established Pichia stipitis fermentation model, and analyzing the efficiency problem of two-tank continuous fermenting glucose and xylose the mixture solution to produce alcohol. The used substrate sources of two-tank continuous fermentation, in accordance with preprocessing, can be classified as 50 g/L pure glucose and the mixture solution of 8 g/L glucose/24 g/L xylose, the two sorts. Therefore, this research is designed that tank-one and tank-two are particular fed one kind of substrates, and the first tank is fed two kinds of substrates at the same time, et cetera, many kinds of operating method, to confer ethanol production rate, ethanol produced ratio, and substrate used ratio, et cetera, the variation under respective sorts of combination, and analyze the ethanol production rate. When comparing two-tank continuous fermenting and one-tank continuous fermenting, two-tank ethanol production rate is not certainly higher, but substrate used ratio is higher. For example of pure glucose fed, one-tank ethanol production rate in dilution rate 0.06 1/hr is 0.24 g/L/hr, and substrate used ratio is 0.265; and two-tank ethanol production rate, in the first and second dilution rate particularly 0.06 1/hr and 0.30 1/hr, is 0.232 g/L/hr, and substrate used ratio is 0.306. And the case of the first tank fed mixture solution substrates and the second tank fed pure glucose of two-tank continuous fermenting, mixture solution fed dilution rate 0.015 – 0.1 1/hr, and pure glucose fed dilution rate 0.050 1/hr, and dilution rate of liquid flowing from the first tank into the second tank 0.0005 1/hr, equivalent to the volume of the second tank being at least 30 times of the volume of the first tank, can get the most ideal ethanol production rate 0.267 g/L/hr, but neither ethanol produced ratio 0.323 nor substrate used ratio 0.34 are ideal. Because dilution rate is lower, ethanol production rate is lower, but ethanol produced ratio and substrate used ratio are higher. That is ethanol produced ratio and substrate used ratio needing sacrificing in order to obtain the highest ethanol production rate.
„Effect of dissolved carbon dioxide on very-high-gravity fermentation“. Thesis, 2012. http://hdl.handle.net/10388/ETD-2012-08-540.
Der volle Inhalt der QuelleHagg, Francois Marius. „The effect of Megasphaera elsdenii, a probiotic, on the productivity and health of Holstein cows“. Diss., 2008. http://hdl.handle.net/2263/27407.
Der volle Inhalt der Quelle- 60% concentrate TMR;
- 60% concentrate TMR with Me dosing;
- 70% concentrate TMR;
- 70% concentrate TMR with Me dosing.
Dissertation (MSc(Agric))--University of Pretoria, 2008.
Animal and Wildlife Sciences
unrestricted
Hu, Wei-Cheng, und 胡維政. „Hydrogen-Productivity Comparison of connected-in-series Reactors of Anaerobic hydrogen-fermentation and Anaerobic photohydrogenesis under Various Operational Conditions“. Thesis, 2005. http://ndltd.ncl.edu.tw/handle/18478586367697547576.
Der volle Inhalt der Quelle臺中師範學院
環境教育研究所
93
Hydrogen-Productivity Comparison of connected-in-series Reactors of Anaerobic hydrogen-fermentation and Anaerobic photohydrogenesis under Various Operational Conditions Abstract The conventional anaerobic wastewater treatment can be used to treat different kinds of organic wastewater and able to recover biogas energy, which is mainly methane. Methane causes to serious green-house effect. Based on the regulation of "the Kyoto Protocol", a clean energy should be sought out in the biomass energy.Due to no-greenhouse effect ,the hydrogenic anaerobic reaction (includes: Anaerobic fermentative hydrogenesis ,anaerobic photohydrogenesis),become a highly potential marketing technique. Based on the past four-years research of our lab.,the CSTR reactor is the most suitable for anaerobic hydrogen fermentation and the plug flow reactor that is the most suitable for anaerobic photohydrogenesis. The fermentative hydrogenic bacteria came from our lab. for long-term cultivation, mainly the Clostridium.The photohydrogenic one came from the lab. of prof. Chi-Mei Lee, Depart. of Environ. Eng., National Chung–Hsing University, which was Rhodopseudomonas palustris (non-sulfur photosynthetic bacteria), coded as WP3-5 .And as the literature mentioned, it is suitable for Anaerobic photosynthetic hydrogenic bacteria to treat the effluent of Anaerobic fermentative hydrogen production process, which contain massive volatile acid. Therefore this research took the main system with the above two kinds of connected in-series reactors, the front stage used the CSTR reactor and the rear stage use the plug flow reactor separated by membrane,and conducted the comparision of hydrogenesis. The results were shown as follows: For various organic loadings and HRTs ,the CSTR of front stage had the best hydrogen-productivity in the case of HRT=2hrs,volume=1.3L. The MLSS could reach 4462mg/l, hydrogen productivity up to 465 mole/m3‧day, per gram of influent COD got up to 3.88 mmole-H2/g-CODin; The secondary highly run was that operating at HRT=4hrs, volume=2L; The third highly run was operated at HRT=6hrs, volume=3L; The fourth highly run was operated at HRT=12hrs, volume=3L.The biomass recycling system can promote MLSS concentration up to 183%,hydrogen productivity up to 233%.The 3 pHs and HRTs tests of the rear-stage plug flow reactor(pH and HRTs of 5.0 and 10hrs,6.5 and 10hrs,5.0 and 24hrs ),the results were shown the photo-hydrogenic reactor had the best hydrogen productivity in the case of pH=5.0 and HRT=10hrs.While the organic loading of 20.4kg-COD/m3‧d,the plug flow reactor had the best hydrogen productivity of 21.5mole-H2/m3‧d, per gram of influent COD got up to 2.30mmole-H2 /g-CODin.The secondary highly run was operated at pH=6.5 and HRT=10hrs and The third highly run was operated at pH=5.0 and HRT=24hrs.In the hydrogen productivity of two connected-in-series system, it had best hydrogen productivity with the front stage reactor of pH =5.25, volume=1.3L, HRT=2hrs and with the rear stage of pH =5.0, HRT=10hrs, the total hydrogen productivity up to 486.5 mole/m3‧day. The front stage hydrogen productivity of CSTR reactor could reach 465 mole/m3‧day and the rear stage of the plug flow reactor could reach 21.5 mole/m3‧day, it was the best connected-in-series system test of ten tests.So the hydrogen production rate of front stage reactor was increased with the increase in organic loading. The photohydrogenic reactor had the best hydrogen productivity in the case of pH=5.0 and HRT=10hrs and was increased with the increase in organic loading. The comparison of hydrogen productivity of connected-in-series reactors and co-cultural reactor, the hydrogen productivity of connected-in-series reactors was better than that of co-cultural reactor.The increased NH3-N concentration and the decreased Org-N concentration of the effluent of front stage reactor was increased with the increase in organic loading, the increased NH3-N and the decreased Org-N of rear stage reactor mainly was increased with the increase in organic loading of front stage reactor (regressional coefficient 0.860 and 0.962), next the influenceial factor was organic loading of next rear stage reactor and was increased with the decreased in organic loading of rear stage reactor (regressional coefficient -0.643 and -0.462). From the observation under the phrase contrast microscope and the fluorescent microscope,the bacterial consortia of the front stage reactor mainly was bacillus of the pale orange fluorescence and the was increased with the increase in organic loading.The rear stage reactor mainly was short bacillus of the faint yellow fluorescece and was increased with the increase in organic loading. From the observation under the SEM,the bacteria of the front stage reactor mainly was bacillus and was increased with the increase in organic loading. When pH=5.0 ,the bacterial consortia of rear stage reactor was more simple and more short bacillus.When pH=6.5, the bacteria was complex.
Vijayan, Uma Rajendra Prasad. „Continuous production of succinic acid with Actinobacillus succinogenes biofilms: Effect of complex nitrogen source on yield and productivity“. Diss., 2016. http://hdl.handle.net/2263/56458.
Der volle Inhalt der QuelleDissertation (MSc)--University of Pretoria, 2016.
National Research Foundation (NRF)
Chemical Engineering
MSc
Unrestricted
Shao-Hsuan, Tseng. „Effects of Polyoxin B and glucose on productivity of 1,3-Beta-glucan of Ganoderma lucidum fermentation broth and Immunopotentiation evaluation“. 2006. http://www.cetd.com.tw/ec/thesisdetail.aspx?etdun=U0001-2707200615345500.
Der volle Inhalt der QuelleTseng, Shao-Hsuan, und 曾勺瑄. „Effects of Polyoxin B and glucose on productivity of 1,3-β-glucan of Ganoderma lucidum fermentation broth and Immunopotentiation evaluation“. Thesis, 2006. http://ndltd.ncl.edu.tw/handle/39189834661272642969.
Der volle Inhalt der Quelle國立臺灣大學
食品科技研究所
94
The objectives of this research were to determine the optimum fermentation condition and to enhance the 1,3-β-D-glucan production of Ganoderma lucidum in submerged culture. The immunopotentiation of the polysaccharide from G. lucidum fermentation was evaluated by the inhibitory ratio of leukemic U937 cell as an model. The basic medium consisted of 5% black soybean, 2% Huangqi and 2% glucose. Furthermore, 1% glucose was added on day 4, 6 and 8, respectively. The effect of feeding time during the 12-day cultivation in 5L fermentor was evaluated. Addition of 1% glucose on day 6 inhibited the 1,3-β-D-glucanase activity and enhanced 1.54-flod 1,3-β-D-glucan in the culture. Moreover, the addition of chitin synthase inhibitor, Polyoxin B (1.5 ppm), probably reduced the binding between the structure glucan and chitin in cell wall, and therefore enhanced 1,3-β-D-glucan content up to 1.68 fold on day 8 without affecting cell growth. The inhibitory ratio of leukemic U937 cell resulted from the G. lucidum polysaccharides was positive correlated to the percentage of 1,3-β-D-glucan, molecular weight and degree of branching. Moreover, significant increases of TNF-α, IL-1β and IFN-γ in the mononuclear condition medium treated with the polysaccharidrs of 1% glucose fed-batch on day 6 were observed.
„The Influence of Controlling Redox Potential on Plasma Membrane Fatty Acid Composition during Very High Gravity Fermentation“. Thesis, 2015. http://hdl.handle.net/10388/ETD-2015-12-2362.
Der volle Inhalt der QuelleNikkhah, Akbar. „Feeding time (2100 h vs. 0900 h) effects on feed intake, rumen fermentation, blood metabolites, and productivity of lactating Holstein cows“. 2007. http://hdl.handle.net/1993/20564.
Der volle Inhalt der QuelleNurhayati und 林海亞. „High-Productivity and Eco-Friendly Bioethanol Production through Integration of Cell Immobilization, Membrane Distillation-Coupled Fermentation, and CO2 Capture & Fixation“. Thesis, 2014. http://ndltd.ncl.edu.tw/handle/53388105716930137837.
Der volle Inhalt der Quelle國立成功大學
化學工程學系
102
Bioethanol as one of renewable energy is considered an excellent alternative clean-burning fuel to replace gasoline. Continuous bioethanol fermentation systems have offered important economic advantages in comparison with traditional systems. Fermentation rates can be significantly improved when the continuous fermentation is integrated with cell immobilization techniques to enrich the cells concentration in the fermenter. Growing cells of Zymomonas mobilis immobilized in polyvinyl alcohol (PVA) gel beads were employed in an immobilized-cell fermenter for continuous bioethanol fermentation from glucose. The glucose loading, dilution rate and cells loading were varied in order to determine the best condition employed in obtaining both high bioethanol production and low residual glucose at high dilution rates. Higher glucose fermentation rate has been considered as the most important target as it leads to higher bioethanol titer and better bioethanol productivity. To enable bioethanol fermentation at high glucose concentration with continuous-flow operations, the Z. mobilis cells were immobilized using polyvinyl alcohol (PVA) matrix modified with a certain amount of iron (III) oxide (Fe2O3) and the cell immobilization of Z. mobilis was simply performed by using the enriched cells culture media harvested at the exponential growth phase. The production of bioethanol was affected by the medium flow rates or hydraulic retention time (HRT) from 1 to 4 hour. In addition, the effects of both initial glucose loadings (100 g/L, 125 g/L and 150 g/L) and cell loadings (20% (w/v), 40% (w/v) and 50% (w/v)) were also investigated. On the other hand, the bioethanol production performance of Z. mobilis cells immobilized with cross-linked polymer of PVA with 1% (w/v), 2% (w/v) and 3% (w/v) of Fe2O3 and unmodified PVA-immobilized Z. mobilis was compared. Reusability of the immobilized Z. mobilis or stability of beads was examined and found that the immobilized cells could be utilized for more than 20 days without losing their activity. Biothanol productivity increased from 15.74 g/L/h to 31.09 g/L/h when the modified PVA-immobilized Z. mobilis with 1% (w/w) of Fe2O3 was employed and the glucose loading was 125 g/L. Moreover, the HRT of 2 hour and cell loading of 40% (w/v) were considered as the optimum conditions to obtain the best bioethanol fermentation performance. The modified PVA-immobilized Zymomonas mobilis cells were used to enhance the efficiency of bioethanol production under very high gravity (VHG) conditions. Continuous bioethanol fermentation was integrated with in-situ bioethanol removal via vacuum membrane distillation (VMD) to overcome the problems associated with product inhibition and the resulting low bioethanol productivity during bioethanol fermentation. The developed VMD-integrated VHG fermentation system can be successfully operated under a feeding glucose concentration of up to 300 g/L (or 30% (w/v)), obtaining a maximum bioethanol concentration of 127.39 g/L (or 16.14% (v/v)), an bioethanol productivity of 63.69 g/L/h, and a glucose conversion of 84.93%. In addition, the production of bioethanol by fermentation must be accompanied by some by-products, such as carbon dioxide (CO2) and organic acids. These by-products can lower the quality and usability of bioethanol as a biofuel and also increase the amount of wastes to cause environmental pollution. CO2 produced from fermentation is of high purity and is nearly a saturated gas (almost 100%). The majority of CO2 applications were dedicated to serving carbonated beverage and food processing/preservation. Beyond these traditional applications, one of the most potential ones is the production of algae-based biofuels through CO2 fixation by microalgae. The advantages of using microalgae CO2 fixation include rapid growth rate and high CO2 fixation capability when compared to conventional plants and high oil/carbohydrate production. The carbohydrate-rich microalgal biomass then can be used for bioethanol production in large scale applications. Photosynthesis is often required for CO2 fixation. The need of solar energy supply in photosynthesis reactions appears to limit the application of biological CO2 sequestration due to scale-up problems. Furthermore, many microorganisms considered for CO2 fixation have fastidious growth requirements. Succinic acid is a common natural organic acid often found in humans, animals, plants and microorganisms. As 1 mol CO2 is theoretically required for the synthesis of 1 mol succinic acid. CO2 should play an important role in succinic acid production to promote the regulation of the PEP carboxykinase pathway. Compared to carbon capture by microalgae, this developed system encourages much higher CO2 fixation rate. The highest carbon fixation rate achieved for microalgae cultivation was 2.06 g/L/d, while it was 31.92 g/L/d (15 times higher) for succinic acid production. Therefore, production of succinic acid is also a feasible way of biological CO2 removal. In the end, bioethanol has to be produced from non-food sources. Cellulosic biomass was used for bioethanol fermentation for the purpose of reducing greenhouse gas emissions and giving impacts to rural economy condition. Cellulosic resources are in general very widespread and abundant. Being abundant and outside the human food chain brings cellulosic materials such bagasse, rice straw, etc. relatively inexpensive feedstocks for bioethanol production. A 120 g/L of bagasse loading or corresponding to 62.79 g/L of glucose after hydrolysis was used to evaluate the feasibility of producing bioethanol with the modified-PVA immobilized Z. mobilis cells. The glucose conversion obtained was about 94.57% in average with a bioethanol titer and productivity of approximately 26.82 g/L and 13.41 g/L/h, respectively, during fermentation. The results demonstrate that the modified PVA-immobilized Z. mobilis cells are preferable cell immobilization system for cellulosic bioethanol production.
Matos, Ana Luísa Dominguez de. „Fructooligosaccharides production - ingredients for functional food“. Doctoral thesis, 2013. http://hdl.handle.net/1822/28652.
Der volle Inhalt der QuelleThis thesis addresses the development and optimization of a fermentation process for the production of fructooligosaccharides (FOS) by fungi. FOS are prebiotics with numerous health benefits within which the improvement of gut microbiota balance can be highlighted, playing a key role in individual health. Conventionally, FOS production is a two-stage process that requires an enzyme production/purification step in order to proceed with the chemical reaction itself. FOS production by fungi in bioreactors in a one-stage process is an emergent alternative, since the use of whole cell as the biocatalyst avoids the need for FOS-producing enzyme purification from the cell extract, thus enabling a more competitive less expensive process. Therefore, the main purpose of this thesis was to develop and optimize a one-stage fermentation process for a more competitive FOS production towards its industrial implementation. Optimization of fermentation conditions to maximize FOS production via sucrose fermentation by Aureobasidium pullulans through response surface methodology, using a compilation of mathematical and statistical techniques, was performed and a significant improvement of the total FOS production yield by using a one-stage process was obtained. Although several microorganisms have been reported to have transfructosylation activity due to fructosyltransferase (FTase) and/or fructofuranosidase (FFase) activities, the search for other fungi with higher transfructosylation activity remains a challenge. By means of a presumptive and indirect colorimetric plate assay developed for the evaluation of transfructosylation activity in fungi, several fungal strains belonging to the Aspergillus and Penicillium species were identified, showing potential as FOSproduction microorganisms. An enzymatic extraction procedure was established to determine the transfructosylation and hydrolyzing activities of the enzymes in the extracellular, intracellular and periplasmic spaces of A. pullulans. Extracellular enzymes were found to have the higher transfructosylation activity, supporting the idea of developing a one-stage FOS production process. Fed-batch sucrose fermentations by A. pullulans with two sucrose feeding profiles (constant feeding and linear feeding) were conducted in order to increase FOS production. A slight increase in FOS production yield was achieved with sucrose linear feeding profile, compared to the batch production process, however FOS productivity decreased significantly. The main advantage to operate in fed-batch mode with a linear feeding profile was shown to be the production of fructofuranosyl nystose (GF4), that can add commercial value to the FOS mixture obtained, since GF4 may exert a prebiotic effect in more distal colonic regions compared with the lower-molecular-weight FOS. The scale-up of the one-stage batch FOS production process from sucrose by A. pullulans, to a semi-pilot scale, was performed. Similar FOS production yield, productivity, composition and kinetics were obtained by a 25 times volume increase scaling up procedure, suggesting that the one-stage batch process has potential to be used at an industrial level. Moreover, based on the process design and economics of an industrial unit built to produce 10.000 tons/year of FOS using the here developed production process, it was demonstrated that lower operational costs can be achieved, when compared to the current two-stage FOS production process. An estimated investment of 20 M€ in a FOS industrial unit can achieve a NPV of 71,5 M€, with a IRR of 45,18 % and ROI of 5 years, presenting itself as a very attractive business opportunity.
Esta tese aborda o desenvolvimento e otimização de um processo de fermentação para a produção de fruto-oligossacáridos (FOS) por fungos. Os FOS são pré-bióticos com inúmeros benefícios para saúde, dos quais se pode destacar o equilíbrio da flora intestinal, desempenhando um papel fundamental na saúde do indivíduo. Convencionalmente, a produção de FOS é um processo em duas etapas, que requer uma etapa de produção/purificação enzimática para que a reação química ocorra. A produção de FOS por fungos em biorreatores, tendo por base um processo de produção por uma só etapa, é uma alternativa emergente, dado que a utilização das células inteiras como biocatalisador evita a purificação das enzimas produtoras de FOS do extrato celular, originando um processo mais competitivo e menos dispendioso. Por esse motivo, o principal objetivo desta tese foi o desenvolvimento e otimização de um processo de fermentação para produção de FOS mais competitivo, numa só etapa, com vista à sua implementação industrial. A otimização das condições de fermentação para maximização da produção de FOS por fermentação de sacarose por Aureobasidium pullulans foi efetuada usando a metodologia de otimização fatorial, com recurso a uma série de ferramentas matemáticas e estatísticas, tendo-se alcançado uma melhoria significativa do rendimento global de produção de FOS por A. pullulans com o processo de produção em uma só etapa. Vários microrganismos são reportados como tendo atividade de transfrutosilação por intermédio das enzimas frutosiltransferase (FTase) e / ou frutofuranosidase (FFase). No entanto, a procura de outros fungos com atividade de transfrutosilação mais elevada permanece um desafio. Através de um ensaio colorimétrico em placa, presuntivo e indireto, desenvolvido para a avaliação da atividade de transfrutosilação em fungos, várias estirpes de fungos dos géneros Aspergillus e Penicillium spp foram identificados como potenciais microrganismos produtores de FOS. Um procedimento de extração enzimática foi estabelecido para determinar as atividades de transfrutosilação e hidrólise das enzimas nos espaços extracelulares, intracelulares e periplasmático de A. pullulans. As enzimas extracelulares demonstraram ter a atividade de transfrutosilação mais elevada, reforçando a ideia do desenvolvimento de um processo de produção numa só etapa. Processos de fermentação semi-contínua de sacarose por A. pullulans, com dois perfis de alimentação (alimentação constante e alimentação linear) foram realizados com a finalidade de aumentar a produção de FOS. Um ligeiro aumento no rendimento de produção de FOS foi conseguido com o perfil de alimentação linear de sacarose, em comparação com o processo de produção descontínuo. No entanto, a produtividade de FOS diminuiu significativamente. A principal vantagem de operar em modo semi-contínuo com um perfil de alimentação linear é produzir frutofuranosil nistose (GF4), que pode incrementar o interesse comercial da mistura de FOS obtida, uma vez que o GF4 pode exercer um efeito pré-biótico em regiões mais distais do cólon, em comparação com os FOS de menor peso molecular. Um aumento de escala no processo de produção de FOS numa só etapa, por fermentação de sacarose por A. pullulans, a uma escala semi-piloto, foi realizado e com um aumento de escala de 25 vezes, foram obtidos semelhantes rendimentos de produção de FOS, composição, produtividade e cinéticas de fermentação, sugerindo que o processo numa só etapa tem potencial para ser usado a um nível industrial. Além disso, com base no processo de conceção e economia de uma unidade industrial para a produção de 10.000 ton/ano de FOS, tendo por base o processo de produção desenvolvido nesta tese, menores custos de operação podem ser obtidos, quando comparados com o atual processo de produção de FOS em duas etapas. Um investimento estimado de 20 M€ numa unidade industrial de FOS pode promover um VAL de 71,5 M €, com uma TIR de 45,18% e um tempo de retorno do investimento de 5 anos, apresentando-se como uma oportunidade de negócio muito atrativa.