冻干保护剂对假单胞菌菌粉存活率的影响

保护剂的添加对提高假单胞菌冷冻干燥菌粉的存活率和贮藏稳定性有显著效果。设计实验对冻干保护剂进行筛选和优化研究,通过单因素实验和正交实验筛选出了最佳保护剂组合:脱脂乳粉10%,山梨醇3%,甘油1%,L-抗坏血酸钠2%,假单胞菌冻干后的存活率可达90%,菌粉25℃存放6个月,存活率为50.2%。     

构巢曲霉冻干菌粉的制备及优化

【背景】目前,用以降解园林绿化废弃物中木质素的菌剂多为液体菌剂或固体菌剂,鲜有对粉状菌剂的研究。【目的】研制高活性冻干菌粉,提高其冻干存活率并优化其工艺,以解决液体菌剂或固体菌剂在运输、储藏及使用上存在的问题。【方法】以一株木质素降解菌构巢曲霉(Aspergillus nidulans)为研究对象,利用真空冷冻干燥法制备冻干菌粉。以菌株的冻干存活率为评价指标,通过单因素试验筛选适于菌株冻干过程的保护剂种类及浓度梯度,再通过正交试验优化冻干菌粉复合保护剂配方。获得配方后,进一步探究冻干菌粉的复水条件和储藏条件。【结果】保护效果较优的4种保护剂成分经复配后对冻干存活率的影响顺序为蔗糖>葡萄糖>脱脂乳粉> α-乳糖。经优化后的保护剂配方以蔗糖15%、葡萄糖1%、α-乳糖10%、脱脂乳粉1%为最佳;复水条件以生理盐水为溶剂,复水30 min为最优。在此条件下制备和使用冻干菌粉,菌株的冻干存活率可达83.33%,有效活菌数可达1.2×10¹⁰ CFU/g。最佳储藏温度为-20 ℃,在此温度下保存28 d后,菌粉活性无明显下降。【结论】该研究获得的制备和储藏构巢曲霉冻干菌粉条件,具有菌株损失率低、可长时间保存的特点,对推进木质素降解菌在实际生产中应用具有积极作用。     

长双歧杆菌DD98冻干保护剂优化及菌粉保存稳定性研究

以长双歧杆菌DD98为研究对象,通过对冻干保护剂配方的优化,冻干菌粉的存活率提高到90%以上。通过进一步稳定性研究,采用保护剂优化配方制备的冻干菌粉在4℃保存24个月后,活菌数仍在1.0×10^10 CFU/g以上,在25℃条件下可以保存12个月,双歧杆菌的存活率在1.0×10^6CFU/g以上,符合FAO/WHO建议食品益生菌活菌数应在1.0×10^6 CFU/g^1.0×10^7CFU/g的标准。     

冷风干燥制备高活菌的恶臭假单胞菌菌粉

【目的】获得高活菌恶臭假单胞菌菌粉,提高菌体干燥及保藏存活率。【方法】选用冷风干燥法制备活菌粉,并优化吸附载体与保护剂。【结果】冷风干燥制备恶臭假单胞菌菌粉干燥存活率普遍达到65%以上,显著优于喷雾干燥(24%);对载体与保护剂进行正交试验优化,确定了载体为混合的硅藻土和碱处理玉米芯粉,混合比为1:2,保护剂(质量比)为甘露醇7%、谷氨酸钠5%、甘油1%,制得菌粉活菌数为1.03×1011 CFU/g,室温保藏30 d和4 °C保藏60 d存活率分别达到40.54%和71.67%。【结论】冷风干燥温度相对较低(10?40 °C),对菌体损伤小,碱处理玉米芯粉、甘露醇和谷氨酸钠是提高菌粉保藏存活率的重要因子,此法克服了革兰氏阴性菌菌粉不易制备和不耐保藏的瓶颈。     

保加利亚乳杆菌冻干保护剂的优化

目的 研究4种常用冻干保护剂的添加量.方法 以保加利亚乳杆菌为出发菌株,以其冻干菌粉活菌数为指标,通过正交试验优化4种常用冻干保护剂的添加量.结果 保加利亚乳杆菌的最佳冻干保护剂配比为乳糖∶谷氨酸钠∶抗坏血酸∶脱脂奶粉=3∶1∶2∶7,其中脱脂奶粉对菌体保护效果极显著(P＜0.01),乳糖对菌体保护效果显著(P＜0.05).结论 通过对保加利亚乳杆菌的4种常用冻干保护剂的添加量进行优化,为保加利亚乳杆菌的冻干工艺提供基础.     

仔猪副伤寒活疫苗中耐热保护剂应用相关参数的研究

【目的】研究并确定耐热保护剂在仔猪副伤寒活疫苗中应用的各参数,为制备细菌耐热保护剂活疫苗提供参考。【方法】将耐热保护剂与制苗菌液等体积混合,分别采用3种常用冻干曲线(1、2、3)进行冻干,抽样检测确定耐热保护剂配套冻干曲线。在确定合适冻干曲线的基础上,进一步研究耐热保护剂与不同菌龄菌液(发酵培养12、15、18和21 h)、不同浓度菌液(菌液终浓度分别为3×1010、5×1010和7×1010 CFU/m L)、不同感作时间(分别作用0、24和48 h)、耐热保护剂的不同保存时间(2-8°C分别保存0、10、20、30和40 d),以及不同分装量(2、3和4 m L)等多种不同参数对疫苗质量的影响。【结果】配套冻干曲线研究表明,曲线2冻干的产品性状、活菌存活率与耐老化指标效果最好;菌龄研究表明,37°C发酵培养18 h(位于对数生长末期或稳定前期),其冻干菌存活率达78%-81%,优于其它时间;配苗试验表明,菌液适宜终浓度为3×1010-5×1010 CFU/m L;最适感作时间为2-8°C感作24 h,冻干菌存活率可达85.3%-90.5%;耐热保护剂保存期试验表明,2-8°C保存40 d与0 d(配制当日)的保护剂冻干效果基本一致;配苗分装量试验表明,7 m L西林瓶中分装3 m L或4 m L,其冻干菌存活率与2 m L基本一致,但耐老化试验中活菌存活率比2 m L略高。【结论】收获发酵培养18 h的菌液、配苗终浓度采用3×1010-5×1010 CFU/m L,使用2-8°C保存40 d内的耐热保护剂,让保护剂与制苗用菌液2-8°C感作24 h,采用3-4 m L进行定量分装,按曲线2冻干为制备仔猪副伤寒耐热保护剂活疫苗的适合参数。     

两种不同保护剂冻干的仔猪副伤寒活疫苗质量比较

【目的】系统比较两种不同保护剂冻干的仔猪副伤寒活疫苗(耐热苗和常规苗)质量指标,为科学评价两种疫苗质量提供参考。【方法】制备耐热苗和常规苗各3批,分别进行物理性状、纯粹性、活菌计数、安全性、剩余水分、真空度和保存期等参数测定和比较,同时比较冻干前后的活菌存活率及耐老化性能。任选耐热苗与常规苗1批,按3×109 CFU分别口服与肌肉注射仔猪各5头,设相同条件下不免疫对照5头,30 d后静脉注射致死量猪霍乱沙门氏菌,临床观察30 d后评估疫苗的效力。【结果】耐热苗及常规苗的物理性状、纯粹性、活菌计数、安全性、剩余水分、真空度均符合现行《中国兽药典》的要求。3批耐热苗冻干菌存活率分别为88.2%、83.1%和86.4%,耐老化试验后的活菌存活率为83.6%、82.9%和88.8%;然而3批常规苗冻干菌存活率分别为52.3%、56.2%和61.4%,耐老化活菌存活率分别为58.5%、60.2%和54.7%。经37°C、7 d耐老化试验结果显示,耐热苗物理性状良好,而常规苗原有团块表面凹陷1/4-1/2。保存期结果表明耐热苗4°C有效期可达24个月,常规苗仅为9个月。仔猪免疫攻毒结果表明,耐热苗肌肉注射及口服免疫均达100%(5/5)保护;常规苗肌肉注射达80%(4/5)保护,口服达100%(5/5)保护,不免疫对照0保护(5/5死亡)。【结论】耐热苗具有较高的冻干菌存活率和良好的耐老化性能,4°C可长期保存且不影响其免疫效力。     

植物乳杆菌发酵、冻干工艺及其益生特性的研究

目的以Lactobacillus plantarum SQ-2506为目标,研究该菌株的发酵、冻干工艺及其益生特性。方法通过对培养基中C源、N源和刺激因子的浓度改变考察对活菌数的影响,从而确定培养基的最佳配方;在确定最佳培养基后做出该菌的生长曲线以确定最佳发酵时间点;同时考察冻干保护剂的配方和预冷时间对菌粉活菌数的影响;此外,对植物乳杆菌进行产酸、产H_2O_2、生物膜形成能力、抑菌特性以及抗氧化能力的检测。结果最佳MRS培养基中葡萄糖浓度为0.8%、酪蛋白胨为0.4%、牛肉粉为0.6%、吐温为0.06%;植物乳杆菌的生长曲线在5h时达到稳定期,此时发酵液活菌数为3.16×10~9 CFU/mL,发酵液的pH为4.45。最佳冻干保护剂的配方:脱脂乳100g/L,蔗糖120g/L,抗坏血酸20g/L,谷氨酸钠30g/L;冻干前对上机液预冻时间为2h,此时菌粉冻干存活率为70.21%。该菌株具有产酸、产H_2O_2能力,并对大肠埃希菌、金黄色葡萄球菌和白色假丝酵母均有一定的抑制作用,形成膜能力较强,且具有一定的抗氧化能力。结论通过培养基成分、发酵条件和冻干工艺的优化以及对其益生特性的研究,为下一步新药开发和规模化生产奠定基础。     

双歧杆菌包埋保存技术工艺研究

采用一种全新的思路和方法,从将双歧杆菌活菌完全隔绝空气和降低其对温度的敏感性出发,运用制备微囊的方法,采用一种药用成膜材料,将包埋与冷冻干燥有机结合起来,在冷冻干燥的同时迅速在双歧杆菌活菌体周围形成一层类似微囊的保护膜,即将双歧杆菌活菌体包埋在保护膜内,从而达到减少甚至避免菌体冻干损伤,提高活菌存活率和收率,延长活菌常温保存期,提高活菌常温稳定性的目的。同时,这种包埋保存技术完全去除了常规冻干辅料——脱脂奶粉,能有效减少冷冻干燥菌粉的吸湿性,更利于活菌保存。用双歧杆菌包埋保存技术制备出的冻干菌粉,其含菌量比用常规冻干保护剂作冻干辅料的冻干菌粉高几百亿个／克,双歧杆菌活菌在37℃的保存期达四个月(相当于常温下保存一年以上),有效地解决了双歧杆菌活菌制剂常温保存期短的技术关键问题。     

枯草芽胞杆菌微生态制剂的研制

采用液体发酵工艺,确定枯草芽胞杆菌的最适发酵条件为:发酵温度30℃,初始pH值7.2,并以1%海藻酸钠和3%明胶组成的混合胶体溶液为囊壁材料,以4%氯化钙作固化剂将枯草芽胞杆菌制成微胶囊剂,稳定性试验结果显示经微胶囊包埋的枯草芽胞杆菌制剂,室温下保存1个月,活菌存活率为98.8%,保存3个月,活菌存活率为50.6%,保存6个月,活菌存活率为15.7%,均高于未经微胶囊化的样品;在4℃冷藏下保存3个月,未经微胶囊化的样品活菌存活率仅为经微胶囊包埋制剂的66.2%。该微胶囊制剂提高了活菌存活率,延长了活菌常温保存期。     

Response Surface Optimization of Lyoprotectant for Lactobacillus bulgaricus During Vacuum Freeze-Drying

The individual and interactive effects of skimmed milk powder, lactose, and sodium ascorbate on the number of viable cells and freeze-drying survival for vacuum freeze-dried powder formulation of Lactobacillus bulgaricus were studied by response surface methodology, and the optimal compound lyoprotectant formulations were gained. It is shown that skim milk powder, lactose, and sodium ascorbate had a significant impact on variables and survival of cultures after freeze-drying. Also, their protective abilities could be enhanced significantly when using them as a mixture of 28% w/v skim milk, 24% w/v lactose, and 4.8% w/v sodium ascorbate. The optimal freeze-drying survival rate and the number of viable cells of Lactobacillus bulgaricus were observed to be (64.41 ± 0.02)% and (3.22 ± 0.02) × 10¹¹ colony-forming units (CFU)/g using the optimal compound protectants, which were very close to the expected values 64.47% and 3.28 × 10¹¹ CFU/g.     

Comprehensive optimization of composite cryoprotectant for Saccharomyces boulardii during freeze-drying and evaluation of its storage stability

Abstract

Saccharomyces boulardii (S. boulardii) is widely adopted in the diarrhea treatment for humans or livestock, so guaranteeing the survival rate of S. boulardii is the critical issue during freeze-drying process. In this study, the survival rate of S. boulardii with composite cryoprotectants during freeze-drying procedure and the subsequent storage were investigated. With the aid of response surface method, the composite cryoprotectants were comprehensively optimized to be lactose of 21.24%, trehalose of 22.00%, and sodium glutamate of 4.00%, contributing to the supreme survival rate of S. boulardii of 64.22?±?1.35% with the viable cell number of 9.5?±?0.07?×?10⁹ CFU/g, which was very close to the expected rate of 65.55% with a number of 9.6?×?10⁹ CFU/g. The accelerated storage test demonstrated that the inactivation rate constant of the freeze-dried S. boulardii powder was k_?18?=?8.04?×?10^?6. In addition, the freeze-dried goat milk powder results exhibited that the inactivation rate constants were k₄?=?4.48?×?10^?4 and k₂₅?=?9.72?×?10^?3 under 4 and 25?°C, respectively. This work provides a composite cryoprotectant formulation that has a good protective effect for the probiotic S. boulardii during freeze-drying process, possessing the potential application prospect in food, medicine, and even feed industry.     

一株凝结芽孢杆菌的分离筛选及产孢条件优化

【背景】凝结芽孢杆菌除了具有一般乳酸菌的益生功能外,还具较强的耐酸、耐胆盐、耐高温、易贮存等生物特性。【目的】从泡菜中筛选一株性能优良的凝结芽孢杆菌用于微生态制剂的制备,并对其产孢率进行优化,为该菌株的进一步工业化生产提供参考依据。【方法】采用选择性培养基通过特定的培养条件,筛选到一株抑菌效果良好的产酸芽孢杆菌,并对其进行特异性引物的鉴定、16S rRNA基因序列分析及生理生化实验。通过单因素及正交试验对菌株的产芽孢条件进行优化。【结果】筛选得到一株凝结芽孢杆菌BC01,该菌株对大肠杆菌(Escherichia coli CVCC 1527)、鼠伤寒沙门氏菌(Salmonella typhimurium CVCC 2228)、产气荚膜梭菌(Clostridium perfringens CVCC 46)、猪霍乱沙门氏菌(Salmonella choleraesuis CVCC 503)等均有较强的抑制作用;模拟胃液处理120 min存活率达到94%;0.3%的胆盐存活率达到84.3%。单因素及正交试验优化后的最适培养基配方:糖蜜10.0 g/L,酵母浸出粉20.0 g/L,NaCl 5.0 g/L,K_2HPO_4 5.0 g/L,MnSO_4 10.0 mg/L;最适培养条件:接种量4%,温度45°C,初始pH 7.0,转速200 r/min,培养时间36 h。在该优化条件下,其活菌数最高达到6.7×10~9 CFU/mL,产孢率达到89.2%。【结论】筛选得到一株可用于微生态制剂的菌株——凝结芽孢杆菌BC01,对其产孢率进行了优化,为工业化生产奠定了基础。     

Persistence of <Emphasis Type="Italic">Isaria fumosorosea</Emphasis> (Hypocreales: Cordycipitaceae) SFP-198 Conidia in Corn Oil-Based Suspension

Long-term persistence of entomopathogenic fungi as biopesticides is a major requirement for successful industrialization. Corn oil carrier was superior in maintaining germination rates of Isaria fumosorosea SFP-198 conidia during exposure to 50°C for 2 h, when compared with other oils, such as soybean oil, cottonseed oil, paraffin oil, and methyl oleate. The corn oil-based conidial suspension (91.6% germination) was also better in this regard than conidial powder (28.4% germination) after 50°C for 8 h. Long-term storage stabilities of corn oil-based conidial suspension and conidial powder at 4 and 25°C for 24 months were investigated, based on the correlation of germination rate with insecticidal activity against greenhouse whiteflies, Trialeurodes vaporariorum. Viability of conidia in corn oil was more than 98.4% for up to 9 months of storage at 25°C, and followed by 23% at 21 months. However, conidial powder had only 34% viability after 3 months of storage at 25°C, after which its viability rapidly decreased. The two conidial preparations stored at 4°C had better viabilities than those at 25°C, showing the same pattern as above. These results indicate that corn oil-based conidial suspension can be used to improve conidial persistence in long-term storage and be further applied to the formulation of other thermo-susceptible biological control agents.     

Storage stability and sourdough acidification kinetic of freeze-dried Lactobacillus curvatus N19 under optimized cryoprotectant formulation

In this study, the response surface methodology was used to optimize the cryoprotective agent (skimmed milk powder, lactose and sucrose) formulation for enhancing the viability of Lactobacillus curvatus N19 during freeze-drying and storage stability of cells freeze-dried by using optimum formulation was evaluated. Our results showed that the most significant cryoprotective agent influencing the viability of L. curvatus N19 to freezing and freeze-drying was sucrose and skim milk, respectively. The optimal formulation of cryoprotective agents was 20 g/100 mL skim milk, 3.57 g/100 mL lactose and 10 g/100 mL sucrose. Using the optimum formulation during freeze-drying, the cell survival was found more than 98%. Under the optimal conditions, although only storage of the cells at 4 °C for 6 month retained the maximum stability (8.85 log cfu/g), the employed protectant matrix showed promising results at 25 °C (7.89 log cfu/g). The storage stability of cells under optimized conditions was predicted by accelerated storage test, which was demonstrated that the inactivation rate constant of the freeze-dried L. curvatus N19 powder was 9.74 × 10⁻⁶ 1/d for 4 °C and 2.08 × 10⁻³ 1/d for 25 °C. The loss of specific acidification activity after the storage at 4 and 25 °C was determined.     

Production of mouse fetuses using spermatozoa exposed temporarily to high temperature or continuously to room temperature after freeze-drying in Na+-free/K+-rich EGTA buffer

Present study aimed to determine to what extent freeze-dried spermatozoa were able to withstand high-temperature conditions: transient increase in storage temperature and long-term exposure to room temperature. Mouse spermatozoa were freeze-dried in EGTA/Tris-HCl buffered solution alkalinized using KOH (K-ETBS, pH 7.7), and then stored for up to 7 months at 4 °C or 25 °C. After 2 months’ storage, some of the 4°C-stored spermatozoa were exposed to 40 °C for 1 week or 1 month, then again stored at 4 °C for the remaining storage period. Following storage, rehydrated spermatozoa were injected into mouse oocytes. The resulting zygotes were assessed for chromosome damage, in vitro development up to the blastocyst stage, and post-implantation development to normal fetuses on day 18 of gestation. In storage at 4 °C, one-week exposure to 40 °C had no adverse effect on the chromosome integrity and developmental competence compared to non-exposure to 40 °C (continuous storage at 4 °C). In contrast, one-month exposure to 40 °C caused an increasing level of chromosome damage (36%, P < 0.05) and reduced frequencies of blastocysts (54%, P < 0.05) and normal fetuses (36%, P < 0.05) compared to the frequencies obtained by continuous storage at 4 °C (15%, 82% and 52%, respectively). Storage at 25 °C resulted in accumulation of chromosome damage (27%, P < 0.05), leading to decreased blastocyst formation (63%, P < 0.05). But, the frequency of normal fetus (44%) was not significantly different from that obtained by continuous storage at 4 °C. Consequently, mouse spermatozoa freeze-dried in K-ETBS withstood temporary exposure to 40 °C for 1 week. Chromosome damage accumulated in spermatozoa during storage at 25 °C.     

Optimising the viability during storage of freeze-dried cell preparations of Campylobacter jejuni

Freeze-dried cultures of Campylobacter jejuni are used in the food and microbiological industry for reference materials and culture collections. However, C. jejuni is very susceptible to damage during freeze-drying and subsequent storage and it would be useful to have longer-lasting cultures. The survival of C. jejuni during freeze-drying and subsequent storage was investigated with the aim of optimising survival. C. jejuni was freeze-dried using cultures of different age (24-120 h), various lyoprotectants (10% phytone peptone, proteose peptone, peptonized milk, trehalose, soytone and sorbitol), various storage (air, nitrogen and vacuum) and re-hydration (media, temperature and time) conditions. One-day-old cultures had significantly greater survival after freeze-drying than older cultures. The addition of trehalose to inositol broth as a lyoprotectant resulted in almost 2 log(10) increase in survival after 2 months storage at 4 degrees C. Storage in a vacuum atmosphere and re-hydration in inositol broth at 37 degrees C increased recovery by 1-2 log(10) survival compared to re-hydration in maximal recovery diluent (MRD) after storage at 4 degrees C. Survival during storage was optimal when a one-day-old culture was freeze-dried in inositol broth plus 10% (w/v) trehalose, stored under vacuum at 4 degrees C and re-hydrated at the same incubation temperature (37 degrees C) in inositol broth for 30 min. The results demonstrate that the survival of freeze-dried cells of C. jejuni during storage can be significantly increased by optimising the culture age, the lyoprotectant, and the storage and re-hydration conditions. The logarithmic rate of loss of viability (K) followed very well an inverse dependence on the absolute temperature, i.e., the Arrhenius rate law. Extrapolation of the results to a more typical storage temperature (4 degrees C) predicted a very low K value of 1.5 x 10(-3). These results will be useful to the development of improved reference materials and samples held in culture collections.     

Factors Affecting the Ascorbate- and Phenolic-dependent Generation of Hydrogen Peroxide in Dulbecco's Modified Eagles Medium

Ascorbate and several polyphenolic compounds have been reported to undergo oxidation in cell culture media to generate hydrogen peroxide (H?0?), but the mechanism underlying this has not been established. We therefore investigated the parameters affecting H?0? production. H?0? gene ration from ascorbate, gallic acid and other phenolic compounds in Dulbecco's Modified Eagles' Medium (DMEM) at 37°C under 95% air - 5% C0? was not significantly inhibited by high (5-10 mM) concentration of EGTA, o-phenanthroline or desferrioxamine, but partial inhibition by EDTA and diethylenetriaminepentaacetic acid (DTPA) was observed. Incubation of DMEM alone at 37°C led to an upward drift of pH, even under an atmosphere of 95% air - 5% C0?. Prevention of this pH rise by increasing the concentration of N-[2-hydroxyethyl]piperazine-N'-[2-ethanesulfonic acid] (Hepes) buffer lowered the levels of H?0? generated by ascorbate and phenolic compounds, but there was still substantial H?0? generated at pH 7.4. Mixtures of ascorbate and phenolic compounds led to less H?0? generation than would be expected from the rates observed with ascorbate or phenolic compounds alone. Ascorbate prevented the loss of gallic acid incubated in DMEM. The role of metal ions and other constituents of the culture medium in promoting H?0? generation is discussed.     

Produktion von Ochratoxin A und B durch<Emphasis Type="Italic">Penicillium verrucosum</Emphasis> auf Gerste in Abhängigkeit der Parameter Wasseraktivität,Wassergehalt und Temperatur

The ochratoxin A and B (OTA, OTB) production by a toxigenic isolate ofPenicillium verrucosum grown on brewing barley up to six weeks was studied at a storage temperature of 25 °C and different moisture and water activity conditions. Sorption isothermes for barley were prepared at temperatures of 10°C, 15°C and 25°C. OTA was produced after 2 weeks of storage at moisture contents of ≥19%, which is equivalent to water activities (a_w) of 0.83 (adsorptive) and 0.82 (desorptive) at 25 °C. Increased OTA concentrations (5.8-fold and 16.1-fold) were noticed when the moisture contents were adjusted to 20% (a_{w [ads]} 25 °C=0.86) and 21% (a_{w [ads]} [ 25 °C=0.88), respectively. An increase was also shown during storage of 4 and 6 weeks (1.2-fold and 2.4-fold, respectively). Production of OTB was shown to occur at moisture contents ≥18% (a_{w [ads]} 25 °C=0.81). The findings document that OTA and OTB are not produced byP. verrucosum grown on barley stored below 18% moisture content.