假丝酵母99-125脂肪酶的发酵工艺研究

对假丝酵母99-125脂肪酶的发酵工艺条件进行了一系列研究。选择了合适的培养基成分并进行优化 ,获得了最优的摇瓶培养基配方 (% ,W/V) :豆油 4.0 ,全脂豆粉 4.0 ,K₂HPO₄0.1,KH₂PO₄ 0.1。产酶水平能达到 5000IU/mL。在 30L发酵罐上进行初步放大实验 ,其产酶水平能达到 8100IU/mL。在1m³发酵罐上进行中试放大 ,产酶水平可达到 8000IU/mL。     

稀释速率对高浓度酒精连续发酵过程振荡行为的影响

在一搅拌罐和三段管式反应器组成的组合反应器系统中,使用葡萄糖浓度为280g/L,添加5g/L酵母膏和3g/L蛋白胨的底物,在总稀释速率分别为0.032h^-1,0.024h^-1,0.017h^-1,0.012h^-1和0.006h^-1的条件下,考察了稀释速率对高浓度酒精发酵系统振荡行为的影响。结果表明,振荡行为在特定的稀释速率条件下呈现,进而基于数学上的分岔理论,分析了振荡行为发生的可能性及对应的稀释速率范围,并与实验结果进行了比较,在此基础上,讨论了振荡行为对酒精发酵过程的影响。     

L－缬氨酸发酵供氧与补料过程控制的研究

高产缬氨酸的北京棒杆菌(corynebacterium pekinense)突变株125菌株,在2．6L自控发酵罐上分批培养结果表明,当发酵中后期DO为零时,产酸量较多。也可用kL。值为指标来调节过程的供氧强度,Kla=90．75h^-1时,产酸量最高。同时比较了恒速连续补加葡萄糖液,当F=3．75g／b时,产酸较高。由此获得了该菌株L一缅氨酸发酵的低供氧与恒速补糖的控制模式。总糖量为16．85％的发酵,可使产酸量达38．2g／L,转化率为22．67％。本文对有关试验结果,进行了发酵动力学的分析和讨论。     

金针菇在淀粉废水中发酵的营养条件研究

用摇瓶试验对金针菇菌丝体在淀粉废水中培养的营养条件进行了研究。结果表明,利用淀粉废水进行金针菇液体发酵的最适营养条件为：经液化处理的淀粉废水,加KH₂PO₄0.25 g/100 mL,MgSO₄·7H₂O0.05g/100mL,V_B1150μg/L,V_B250μg/L,pH5.40。测定了该营养条件下菌体的生长曲线及发酵过程中培养基残糖的变化。发酵周期为7d,发酵终点生物量达2.08 g/100 mL,COD去除率为70.8%。     

枯草芽孢杆菌B115优化培养及其对气单胞菌的抗菌效果的研究*

采用正交实验设计确定了枯草芽孢杆菌(Bacillus subtilis)B115的基础培养基成份为:胰蛋白胨1%,酵母膏0.25%,氯化钠0.5%;添加成份最优组合为(NH₄)₂SO₄0.1%,(K₂HPO₄+KH₂PO₄)(1.4+0.6)%和柠檬酸三钠0.1%;添加成分最优组合与基础培养基培养产量比较,表明添加K⁺     

甲醇抑制时重组毕赤酵母发酵的特性研究

本文对毕赤酵母进行了恒化培养研究。以甲醇为唯一碳源时,在稀释率较低时(D<0.048 h^-1),连续培养系统操作很稳定。但在稀释率高时(D>0.048h^-1),连续培养系统的定态点不止一个,实验不能维持,故采用比生长速率恒定的分批流加培养进行研究。结果表明,毕赤酵母的生长符合Andrew普遍化底物抑制模型。综合考虑水蛭素的生成、底物的消耗,在生产中维持甲醇浓度为限制性浓度(0.5 g/L),且维持比生长速率为0.02 h^-1时,水蛭素Hir65的比生成速率达到最大值0.2 mg/(g·h)且甲醇的比消耗速率为0.04 g/(g·h)。     

固定化纤维二糖酶的研究

黑曲霉（Aspergillus niger LORRE 012）的孢子中富含纤维二糖酶,将这些孢子用海藻酸钙凝胶包埋后,可以方便有效地固定纤维二糖酶。固定化后的纤维二糖酶性能稳定,半衰期为38 d,耐热性和适宜的pH范围均比固定化前有所增加,其K_m和V_max值分别为6.01 mmol/L和7.06 mmol/(min·L)。利用固定化纤维二糖酶重复分批酶解10 g/L的纤维二糖,连续10批的酶解得率均可保持在97%以上;采用连续酶解工艺,当稀释率为0.4 h^-1,酶解得率可达98.5%。玉米芯经稀酸预处理后,其纤维残渣用里氏木霉（Trichoderma reesei）纤维素酶降解,酶解得率为69.5%;通过固定化纤维二糖酶的进一步作用,上述水解液中因纤维二糖积累所造成的反馈抑制作用得以消除,酶解得率提高到84.2%,还原糖中葡萄糖的比例由53.6%升至89.5%,该研究结果在纤维原料酶水解工艺中具有良好的应用前景。     

保水功能菌枯草芽胞杆菌LX-1固态发酵的工艺优化

γ-聚谷氨酸(γ-PGA)对土壤保水和提高植物抗逆性具有明显作用,为了利用农产品加工下脚料发酵生产含有γ-PGA的保水功能肥料,对福建省微生物研究所环境微生物研究室分离到的产γ-PGA的枯草芽胞杆菌(Bacillus subtilis)LX-1的固态发酵培养基配比进行优化。实验以发酵产物的荧光素双醋酸酯酶(FDA)酶活和增比黏度为指标,在通过单因素实验选定固态发酵料的碳源、氮源、无机盐溶液的最佳配比以及无机盐较佳添加量的基础上,通过拟水平均匀设计U₇* (7⁴试验,得出菌株LX-1固态发酵的最佳培养基配方：V豆粕V麦麸V无机盐溶液=644,其中无机盐溶液的最佳配方为K₂HPO₄·3H₂O 5.24 g/L、MgSO₄·7H₂O 0.78 g/L、NaCl 11.67 g/L。为利用农产品加工下脚料发酵生产含γ-PGA保水肥料提供参考。     

喷射自吸管式生化反应器研究

本文研究了喷射自吸管式生化反应器的吸气及所液传质特性,提出了吸气量(Qs)和容积氧传递系数(kLa)的数学表达式：Qg=5.2×10^-2W^0.144_cLR^0.079_cD(L-D)^0.328D²_nPoπ——P^o_gTo[(D-Dn)²-1](Pn-Pl)-1)(Kla)₁=0.999(W-V)^0.38V^0.90_sg(L-D)^-0.16(Kla)2=1.003(W-V)^0.71V^0.28_sg(L-D)^-0.32(加C圈)反应器的具优工况为：L/D=320-400,D/D=2.7—3。8,Pn=5—13×10⁴N/m²。Kla最高达4280h^-1,比能耗为0.72—2.16×10³kJ/kgO₂用于培养饲料酵母,酵母浓度达40.04kg/m³.最大生长速率为6.24kg/m³·h,比能耗为1.66—2.52×10³KJ/kg DBM.空气利用率为10—20%.是一般生化反应器的2—4倍。     

嗜线虫致病杆菌产生抗生素的培养基及条件*

本文对嗜线虫致病杆菌 (Xenorhabdus nematophilus)产生抗生素的发酵培养基和发酵条件进行了研究 ,同时对该菌代谢过程 p H值、还原糖、总糖、氨基氮与抗生素产量的关系进行了分析。通过筛选该菌对碳源和氮源的要求 ,用正交试验初步确定了该菌产素的最佳发酵培养基和条件为 :玉米粉 1% ,大豆粉 3% ,蔗糖 1% ,蛋白胨 1.5% ,KH₂ PO₄ 0 .0 2 % ,Mg SO₄ 0 .2 % ,活化剂     

自絮凝颗粒酵母乙醇连续发酵耦合酵母回用工艺的研究

模拟现有酒精发酵行业普遍采用的多级发酵罐串联系统,建立了一套由三级串联操作的搅拌式发酵罐和两个沉降罐组成的反应器系统,以脱胚脱皮玉米粉双酶法制备的糖化液为发酵底物,培养基初始还原糖浓度为220g/L,添加(NH4)2HPO41.5g/L和KH2PO42.5g/L,以0.057h-1的恒定稀释速率流加,将自沉降浓缩后的酵母乳先后经活化和不活化两种方式处理并循环至第一级发酵罐,系统在两种操作条件下分别达到了拟稳态。实验结果表明活化处理对改善发酵工艺技术指标方面发挥了显著的作用,发酵终点乙醇浓度达到101g/L,还原糖和残总糖分别在3.2和7.7g/L左右,发酵系统的设备生产强度指标为5.77g/(L.h),与无酵母回用的搅拌式反应器系统中自絮凝颗粒酵母乙醇发酵工艺相比,提高了70%。     

Ethanol fermentation in a yeast immobilized tubular fermentor

In this article, a mathematical model describing the kinetics of ethanol fermentation in a whole cell immobilized tubular fermentor is proposed. Experimental results show reasonable agreement with the proposed model. A procedure for treating the fermentation data for determining the ethanol inhibition constants k(1) and k(2) is described. The ethanol productivity of the immobilized cell fermentor is compared with those of traditional fermentors. Experimental studies indicate that with Saccharomyces cerevisiae (NRRL Y132) culture, ethanol productivity in the range 21.2-83.7 g ethanol L(-1) h(-1) at ethanol concentration of 76-60 g/L can be achieved. This is comparable to or higher than those reported in the literature for yeast. The product yield factor of 0.5 g ethanol/g glucose was obtained. The immobilized cell fermentor does not show washout at dilution rates of 7 h(-1) and shows good stability over a 650-h operating period.     

Lantana camara for fuel ethanol production using thermotolerant yeast

AIM: Evaluation of Lantana camara's use as feedstock for fuel ethanol production. METHODS AND RESULTS: Lantana camara plant material was hydrolysed with 1% sulfuric acid for 18 h at room temperature, followed by heat treatment of 121 degrees C for 20 min. Hemicellulosic hydrolyzate was separated and used for detoxification by ethyl acetate and overliming. Cellulosic fraction was hydrolysed with Aspergillus niger crude cellulase enzyme for 18 h at 55 degrees C. Using 15% (dw/v) substrate 73 g l(-1) total reducing sugars were obtained to give 78.7% hydrolysis of carbohydrate content. Acid and enzyme hydrolyzates were mixed equally and used for fermentation with thermotolerant Saccharomyces cerevisiae (VS(3)). Yeast fermented L. camara hydrolyzate well with a fermentation efficiency of 83.7% to give an ethanol yield of 0.431 +/- 0.018 g ethanol pre g sugar and productivity of 0.5 +/- 0.021 g l(-1) h(-1). CONCLUSIONS: Even though inhibitors were present in L. camara hydrolyzate, maximum sugars were utilized by thermotolerant yeast. SIGNIFICANCE AND IMPACT OF THE STUDY: Use of L. camara for fuel ethanol production with improved strains and detoxification can be recommended.     

自絮凝颗粒酵母酒精高浓度连续发酵的研究

在四釜串联气升环流悬浮床生物反应器系统中 ,进行了絮凝颗粒酵母酒精连续发酵的研究。以CO2 为驱动动力 ,发酵液液蒸馏废液全循环 ,稀释率为 0 2 h。发酵成熟醑酒精平均浓度为 96 6g L ,残余还原糖和总糖分别为 1 2g L和 4 1g L。     

沙柳原料高浓度底物酶解发酵乙醇工艺

为了提高沙柳生物转化过程的经济可行性,考察了沙柳原料经过蒸爆、超微粉碎+稀酸、超微粉碎+稀碱预处理后高浓度底物补料酶解的效果,并对其高浓度水解糖液进行了乙醇发酵。结果表明:蒸爆处理法水解效果最好,通过补料酶解,底物质量分数可以达到30%,酶解液中总糖质量浓度达到132 g/L,葡萄糖质量浓度105 g/L;超微粉碎+稀酸预处理原料底物质量分数可以达到22%,酶解液中总糖质量浓度达到123 g/L,葡萄糖质量浓度73 g/L;超微粉碎+稀碱预处理原料底物质量分数可以达到22%,酶解液中总糖质量浓度133 g/L,葡萄糖质量浓度77 g/L。3种预处理使沙柳原料的酶解糖液都可以较好地被酿酒酵母利用发酵产乙醇,蒸爆处理原料的酶解糖液乙醇发酵效果最好,乙醇质量浓度达到47 g/L。     

鹰嘴豆孢克鲁维酵母利用菊芋原料同步糖化与发酵生产乙醇

菊芋含有大量的菊粉多糖,且种植简单、产量高,是极具开发价值的替代玉米等粮食作物生产燃料乙醇的原料。文中研究了鹰嘴豆孢克鲁维酵母Y179利用菊芋原料同步糖化与发酵生产乙醇。鹰嘴豆孢克鲁维酵母Y179具有高效分泌菊粉酶的能力,摇瓶试验显示Y179酵母能够利用完全由菊芋原料配制而成的培养基良好生长并发酵产生乙醇。通气及温度对乙醇产量影响明显,相对厌氧环境对Y179酵母发酵产乙醇具有促进作用,30℃发酵温度相对37℃和42℃更有利于乙醇产量提高。种子液培养时间及接种量对乙醇产量影响较小。在5 L发酵罐中以10%(V/V)量接入预培养36 h的Y179种子液,发酵液完全由菊芋干粉配制而成,总糖含量22%(W/V),30℃不通气,300 r/min搅拌,发酵144 h时,乙醇浓度达到12.3%(V/V),糖醇转化效率86.9%,糖利用率大于93.6%。初步研究结果显示鹰嘴豆孢克鲁维酵母Y179在利用菊芋原料生产乙醇方面具有良好应用前景。     

Ethanol fermentation of crude acid hydrolyzate of cellulose using high-level yeast inocula

High-level yeast inocula was investigated as a means of overcoming the toxicity problem in ethanol fermentation of acid hydrolyzate of wood cellulose. When the inoculum level exceeded 10(8) initial cells/mL, 50% of the yeast cells survived the initial cell death period during which furfural and HMF were depleted. The fermentation thus proceeded to completion by virtue of cell regrowth. The specific ethanol productivity in batch fermentation on the basis of viable cells was comparable to that of pure glucose fermentation. Continuous fermentation with cell recycle was superior to batch fermentation in that there was no overall cell decline and the ethanol yield was substantially higher. The maximum ethanol productivity in continuous fermentation was 4.9 g/L h and it occurred at a dilution rate of 0.24 hr(-1).     

In situ detoxification and continuous cultivation of dilute-acid hydrolyzate to ethanol by encapsulated S. cerevisiae

Dilute-acid lignocellulosic hydrolyzate was successfully fermented to ethanol by encapsulated Saccharomyces cerevisiae at dilution rates up to 0.5h(-1). The hydrolyzate was so toxic that freely suspended yeast cells could ferment it continuously just up to dilution rate 0.1h(-1), where the cells lost 75% of their viability measured by colony forming unit (CFU). However, encapsulation increased their capacity for in situ detoxification of the hydrolyzate and protected the cells against the inhibitors present in the hydrolyzate. While the cells were encapsulated, they could successfully ferment the hydrolyzate at tested dilution rates 0.1-0.5h(-1), and keep more than 75% cell viability in the worst conditions. They produced ethanol with yield 0.44+/-0.01 g/g and specific productivity 0.14-0.17 g/(gh) at all dilution rates. Glycerol was the main by-product of the cultivations, which yielded 0.039-0.052 g/g. HMF present in the hydrolyzate was converted 48-71% by the encapsulated yeast, while furfural was totally converted at dilution rates 0.1 and 0.2h(-1) and partly at the higher rates. Continuous cultivation of encapsulated yeast was also investigated on glucose in synthetic medium up to dilution rate 1.0 h(-1). At this highest rate, ethanol and glycerol were also the major products with yields 0.43 and 0.076 g/g, respectively. The experiments lasted for 18-21 days, and no damage in the capsules was detected.     

The performance of serial bioreactors in rapid continuous production of ethanol from dilute-acid hydrolyzates using immobilized cells

The performance of single, and series of, continuous stirred-tank (CSTBR) and fluidized-bed bioreactor (FBBR) in anaerobic continuous cultivation of glucose in defined media and dilute-acid hydrolyzates at dilution rates 0.22, 0.43, 0.65 and 0.86 h(-1) using immobilized Saccharomyces cerevisiae CBS 8066, was investigated. While the single CSTBR and FBBR could not take up more than 77% and 92% of glucose in a defined medium at dilution rate 0.86 h(-1), addition of the second bioreactor decreased the residual glucose to less than 1.1% of the incoming sugar. A similar trend was obtained in cultivation of dilute-acid hydrolyzates. A CSTBR could take up 75% and 54% of the initial fermentable sugars at dilution rates 0.43 and 0.86 h(-1), while the addition of the FBBR improved the assimilation of the sugars to 100% and 86%, respectively. The ethanol yields from the hydrolyzate were between 0.41 and 0.48 g/g in all the experiments. The specific and volumetric ethanol productivities were 1.13 g/gh and 5.98 g/Lh for the single bioreactor and 0.98 g/gh and 5.49 g/Lh for the serial bioreactor at the highest dilution rate, respectively. Glycerol was the only important by-product in terms of concentration, and yielded 0.05-0.07 g/g from the hydrolyzate. From the initial 3.98 g/L acetic acid present in the hydrolyzate, 0.1-0.8 g/L was assimilated by the cells. The yeast cells were accumulated close to the surface of the beads. While the cells had a dry-weight concentration of 129 g/L close to the surface of the beads, the concentration in the core was only 13 g/L.