蛹虫草菌丝产虫草素液体培养条件的研究

通过对蛹虫草菌丝产虫草素液体培养条件的研究,明确蛹虫草菌丝产虫草素的适宜碳源及浓度,适宜氮源及浓度,最适pH值,最适培养温度,最适转速以及最适培养时间,以便应用于虫草素的工厂化生产。结果表明,蛹虫草菌丝产虫草素的条件：适宜碳源为D-果糖,最适浓度为10g/L;适宜氮源为蛋白胨,最适浓度为15g/L;最适初始pH为7,最适培养温度为24℃,最适转速为180r/min,最适培养时间为9d,其培养液虫草素含量可达到0.537g/L。     

黑曲霉GD-6纤维素酶液体发酵条件的研究

采用黑曲霉 (Aspergillusniger)GD 6液体发酵生产纤维素酶 ,研究了碳源、氮源、培养基起始 pH值、接种量、摇床转速、通气量对该菌株产纤维素酶活力的影响。结果表明 ,GD 6的最适发酵温度为 2 8～ 3 0℃ ,产酶pH为 5 .5～ 6.0 ,摇床最适转速为 1 5 0r/min ,最佳接种量为 1 0 %。在以 6.0 %稻草粉为碳源、1 %豆饼粉为氮源时产酶活力最高。在最适培养条件下 ,发酵周期为 1 2 0h,发酵液中CMC酶活为 1 88.6U/mL ,FP酶活为 2 7.0U/mL。     

低温碱性蛋白酶菌株的筛选及产酶条件的研究

从 2 0株枯草芽孢杆菌筛选出了 1株产低温碱性蛋白酶菌株 ;并通过单因子实验、正交实验确定该菌株的最佳培养基为 :葡萄糖 8%,豆粕粉 6 %,Tween80 0 .0 3%,KH2 PO4 0 .0 6 %;确定了酶作用的最适条件为 30℃。     

褐变蚕蛹分离蛋白脱色与改性研究

研究了褐变蚕蛹分离蛋白脱色方法及其酸酐、硫酸锆改性。用酸性乙酸酐法处理蚕蛹分离蛋白质 ,可获得白色脱色物 ,其最佳条件是 ,蚕蛹分离蛋白∶乙酸酐∶H2 O2 =1∶1.2 5∶1.5、温度≥ 80℃、时间≥ 30min。过氧乙酸的作用可能是使参与褐变的赖氨酸ε 氨基重新游离并断开胱氨酸之间的二硫键。乙酸酐或顺丁烯二酸酐修饰赖氨酸ε 氨基的最适条件是 :脱色蛋白∶乙酸酐 (或顺丁烯二酸酐 ) =1∶0 .3(或 0 4 )、pH 9.0～ 9.5、温度≤ 4 5℃、时间 6 0min。硫酸锆修饰氨基和羧基的最适条件是 :脱色蛋白∶硫酸锆 =1∶0 .0 4、pH≤ 3.0、温度≥ 80℃、时间 10min。脱色蛋白经过乙酸酐或顺丁烯二酸酐、硫酸锆修饰 ,其白色可稳定 ,在pH 2～ 12及 80℃条件下均不变色。在碱性条件下 ,H2 O2 可部分氧化蚕蛹分离蛋白褐色 ,获得乳黄色脱色物 ,其最适条件是 ,蚕蛹蛋白∶H2 O2 =1∶1.5、pH 9.0～ 9.5、温度≥ 80℃、时间≥30min。蚕蛹蛋白褐变的原因可能主要是其赖氨酸ε 氨基与氨基葡萄糖在碱性加热条件下发生Marl laid反应所致。此外 ,蛋白质中游离α 氨基、谷氨酸γ 羧基及天门冬氨酸β 羧基可能也参与了褐变反应     

蛹虫草液体培养条件优化及有效成分含量分析

为优化蛹虫草菌的液体培养条件,对蛹虫草菌丝体进行液体摇瓶培养。以干菌丝体得率为指标,对影响发酵产量的重要因子设计正交试验,得出最佳培养条件。在最优条件下扩大培养,检测此时菌丝体中虫草素及虫草多糖含量。结果表明:蛹虫草菌丝体液体发酵的最适条件为:接种量10 % (v/v) ,发酵初始pH7 0 ,发酵温度2 7℃,发酵时间96h。扩大培养后,测得菌丝体中虫草素的含量为5 1 785mg/10 0g ,虫草精多糖含量为1 92g/10 0g。     

黑色葡萄状穗霉S607耐碱性纤维素酶发酵条件的研究

研究了耐碱性纤维素酶生产菌株黑色葡萄状穗霉S6 0 7(StachybotrysatraS6 0 7)的产酶条件。结果表明 ,S6 0 7的最适生长和产酶 pH为 7.0 ,最适产酶温度为 2 8℃ ,摇床最适转速为 180r/min。在以 2 .0 %纤维素粉和 2 .5 %的麸皮作为碳源时产酶最高 ,添加含 (NH4 ) 2 SO4 、尿素和蛋白胨的复合氮源对生长和产酶有明显的促进作用。在最适培养条件下 ,发酵周期为 4～ 5d ,发酵液中CMC酶活为 2 .12IU /mL ,FP酶活为 1.0 3IU /mL ,β 葡萄糖苷酶活为 0 .86IU /mL。     

β-甘露聚糖酶产生菌R10的产酶特性研究

分离出一株能利用魔芋飞粉和魔芋精粉生产β-甘露聚糖酶的解淀粉芽孢杆菌(Bacillus amyloliquefaciens)R10。其摇瓶最适发酵条件为：魔芋飞粉1％(m／m),魔芋精粉2％(m／m),160r/min,37℃培养10h。实验结果表明β-甘露聚糖酶的最适作用温度为60℃,最适作用pH为6．0。魔芋葡甘露聚糖经酶降解后为一系列低聚糖。     

拉曼被孢霉F_5发酵生产γ—亚麻酸的研究

对拉曼被孢霉突变株F5发酵生产γ—亚麻酸的最适碳源、氮源、发酵时间及温度、无机盐离子添加、最适碳源浓度及补加碳源时间等发酵条件进行了研究探讨。最适发酵培养基组成为 (g/L) :葡萄糖 1 0 0 ,酵母浸出粉 4 ,蛋白胨 1 ,K2 HPO4 1 ,CaCl2 1× 1 0 - 2 ,MgSO4 5× 1 0 - 2 ,FeSO4 1× 1 0 - 2 ,ZnSO4 7.5× 1 0 - 3,CuSO4 0 .5× 1 0 - 3,MnSO4 2× 1 0 - 3,pH 6.0。培养温度为 2 5℃ ,1 4 0r/min振荡培养 1 0天 ,培养 8天后 (即收获前 2天 )补加 5 %葡萄糖。发酵结果为 :DC 2 4 .5 9g/L ,TL 1 0 .84g/L ,TL/DC 4 4.0 9% ,GLA/TL 1 0 .67% ,GLA产量为 1 1 5 6.63mg/L。GLA产量较初始结果提高 1 5 6.1 5 %。该菌株已达到工业化生产菌株要求     

小菜蛾酪氨酸酶生物化学性质研究

采用时间动力学法对小菜蛾Plutella xylostella酪氨酸酶的最适反应条件、对抑制剂的敏感度以及发育期变化规律进行了研究。结果表明：小菜蛾酪氨酸酶反应的最适pH值为6.4,反应线性时间为0～2 min,在22℃和4℃下其活性分别可保持12 h 和72 h,在-20℃下至少可保持7 天。不同发育阶段小菜蛾酪氨酸酶活性的大小依次为预蛹＞4龄幼虫＞蛹＞1龄、2龄、3龄幼虫＞成虫。苯基硫脲（phenyl thiourea,PTU）对小菜蛾阿维菌素抗性品系和敏感品系酪氨酸酶活性的抑制中浓度（I₅₀）值分别为1.1796 μmol/L和1.2795 μmol/L,二者无明显差异。     

超临界CO_2和微波辅助萃取艾叶挥发油工艺的研究

通过超临界CO2萃取均匀设计实验和微波辅助萃取艾叶挥发油的正交实验比较,考察影响提取的主要因素,寻求最佳萃取工艺。超临界CO2萃取最佳工艺条件为:萃取压力16MP,萃取温度31℃,CO2流量20kg/h和时间80min,得率3.75%;微波萃取最佳工艺条件为:辐射功率720w,辐射时间200s,溶剂量400mL,洗涤剂量50mL,得率4.85%。水蒸馏法提取率为1.87%。结果表明超临界CO2和水蒸馏法萃取艾叶挥发油品质最好;微波萃取收率最高,但品质较差。     

Optimization and validation of a high-performance liquid chromatographic method with UV detection for the determination of pyrrole-imidazole polyamides in rat plasma

A simple and sensitive high-performance liquid chromatography (HPLC) method utilizing UV detection was developed for the determination of plasma pyrrole (Py)-imidazole (Im) polyamides in rats and applied to the pharmacokinetic study of compounds. After deproteinization of plasma with methanol, Py-Im polyamides were analyzed with a reversed-phase TSK-GEL ODS-80TM (4.6 mmx15.0 cm TOSOH Co., Japan) column maintained at 40 degrees C. The mobile phase solvent A was 0.1% acetic acid and the solvent B was HPLC-grade acetonitrile (0-10 min, A: 100-20%, B: 0-80% linear gradient; 10-15 min, A: 40%, B: 60%). The flow rate was 1.0 ml/min. The detection wavelength was set at 310 nm. The method was used to determine the plasma concentration time profiles of Py-Im polyamides after intravenous injection.     

无花果果皮中花青素的提取工艺的建立

本研究使用单因素方法考察了无花果(Ficus carica L.)果皮中花青素的最佳提取条件,并考察了7种参数对花青素提取率的影响。参数设置如下:溶剂性质(水,甲醇,乙醇和丙酮)、提取次数(1~3次)、固液比(1/50,1/100,1/150和1/200)、提取时间(60 min,120 min,180 min和240 min)、甲醇浓度(0,20%,40%,60%,80%和100%)、酸类型(盐酸,乙酸,柠檬酸和酒石酸)和酸浓度(0,1%,2%,5%和10%)。使用pH-示差法测量无花果果皮中单体花色素的含量。研究显示,无花果果皮中花青素的最佳提取条件为:溶剂为甲醇溶剂,提取次数为2次,固液比为1/100,提取时间为180 min,甲醇浓度为80%,酸类型为柠檬酸,柠檬酸浓度为5%。该最佳提取条件下的花青素的提取率达到最高(345.62 mg/100g DS)。     

Acetic acid production from whey lactose by the co-culture ofStreptococcus lactis andClostridium formicoaceticum

Summary Acetic acid was produced from anaerobic fermentation of lactose by the co-culture ofStreptococcus lactis andClostridium formicoaceticum at 35° C and pHs between 7.0 and 7.6. Lactose was converted to lactic acid, and then to acetic acid in this mixed culture fermentation. The overall acetic acid yield from lactose was about 95% at pH 7.6 and 90% at pH 7.0. The fermentation rate was also higher at pH 7.6 than at pH 7.0. In batch fermentation of whey permeate containing about 5% lactose at pH 7.6, the concentration of acetic acid reached 20 g/l within 20 h. The production rate then became very slow due to end-product inhibition and high Na⁺ concentration. About 30 g/l acetate and 20 g/l lactate were obtained at a fermentation time of 80 h. However, when diluted whey permeate containing 2.5% lactose was used, all the whey lactose was converted to acetic acid within 30 h by this mixed culture.     

Combined use of acetic acid treatment and modified atmosphere packaging for extending the shelf-life of chilled chicken breast portions

Samples of chicken breasts with skin were treated with a 1% acetic acid solution or untreated and packaged in a 70% CO2/30% N2 modified atmosphere. Two different types of films were studied to establish their usefulness within the above pre-determined conditions. After 3, 7, 14 and 21 d of storage at 4 degrees C, the samples were evaluated for spoilage microbial growth, odour and slime, as well as the gas composition in the headspace volume in the package. As a result of this, it was found that both films were adequate for using them as barriers. Samples treated with the acetic acid solution smelt slightly acidic and pleasant, while the untreated ones had 'off' odours at the end of the storage periods. However, all samples showed acceptable overall aspect by that time. Acetic acid treatment produced decreases in counts in all genera studied. Results of this study indicate that using modified atmosphere packaging (MAP) on chicken breasts previously decontaminated with acetic acid is a worthwhile technology to extend samples shelf-life.     

Removal of acetic acid and sulfuric acid from biomass hydrolyzate using a lime addition–capacitive deionization (CDI) hybrid process

In this study, we developed a lime addition–capacitive deionization (CDI) hybrid process that can efficiently remove acetic acid and sulfuric acid from the model mixture of glucose, xylose, acetic acid, and sulfuric acid, which are the major components from the biomass hydrolyzate by acid hydrolysis. The key parameters of lime addition process (type of lime, amount of lime, stirrer speed, and reaction time) and CDI process (voltage, flow rate, and feed concentration) were also optimized. In the lime addition process, the optimal lime type, (sulfuric acid + acetic acid)/lime molar ratio, stirrer speed, and reaction time for the removal of sulfuric acid were CaCO₃, 1:1, 200 rpm, and 6 min, respectively. For the CDI process, the optimal voltage and flow rate were 1.2 V and 20 mL/min, respectively. The efficiency of acid removal increased as the initial acetic acid concentration decreased. This hybrid process was able to remove 98.08% of sulfuric acid and 76.97% of acetic acid from the mixture of glucose, xylose, acetic acid, and sulfuric acid. The process was able to recover almost all sugar (>99%) at high purity (97.53%).     

Enhanced Differentiation of Zaprionus Chromosomes by Prestaining Acid Hydrolysis

Two variations of orcein staining have been adapted to salivary gland chromosomes of Zaprionus. Method I: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, stained with 2.5% orcein in 60% acetic add for 15-20 min, and squashed in 60% acetic acid. Method II: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, transferred to a saturated solution of carmine in 45% acetic acid for 1 min, then to a mixture of 50 ml of 1% orcein in concentrated lactic acid and 50 ml of 30% acetic add for 5 min. They are squashed in the same mixture. The unproved differentiation of chromosomes from cytoplasm is attributed to the removal of cytoplasmic ribonucleic add by add hydrolysis.     

Staining Sex Chromatin; Biebrich Scarlet and Fast Green Fcf as a Mixture Versus Their Use in Sequence

Human skin was fixed in Davidson's solution (95% alcohol, 35; formalin, 20; glacial acetic acid, 10; and distilled water, 35—parts by volume) and sections prepared through paraffin embedding in the usual manner. Stock stains were: I(BS)—Biebrich scarlet, 1 gm in 100 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid and 5 ml of glacial acetic acid were added—and II(FG)—fast green, 0.5 gm in 85 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid, 0.3 gm of phosphomolybdic acid, and 15 ml of glacial acetic acid were added. Experimental staining solutions were prepared in the following proportions of stock BS to stock FG—1:1, 2:1, 3:1, 1:2 and 1:3. Sections were brought to 50% alcohol and stained for 15, 20, 25 and 30 min in each of the five BS-FG mixtures, rinsed in 50% alcohol, then dehydrated in 70%, 95%, and absolute alcohol, 2 min each; cleared in xylene, and covered in balsam. The 2:1 (optimum proportion) combination of BS with FG, acting for 20 min, yielded 97% sex chromatin-positive nuclei in female material. If sections were stained in stock solution BS for 2 min, they could be differentiated by a 20 min treatment in the mordanting component of stock FG (without dye) to give a one-color stain. Such stains gave about the same percentage of sex chromatin-positive nuclei as those obtained by the regular two-color procedure. These modifications are simpler, more rapid, and yield results comparable to previously employed techniques.     

Staining Sex Chromatin; Biebrich Scarlet and Fast Green Fcf as a Mixture Versus Their Use in Sequence

Human skin was fixed in Davidson's solution (95% alcohol, 35; formalin, 20; glacial acetic acid, 10; and distilled water, 35—parts by volume) and sections prepared through paraffin embedding in the usual manner. Stock stains were: I(BS)—Biebrich scarlet, 1 gm in 100 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid and 5 ml of glacial acetic acid were added—and II(FG)—fast green, 0.5 gm in 85 ml of 50% alcohol to which 0.3 gm of phosphotungstic acid, 0.3 gm of phosphomolybdic acid, and 15 ml of glacial acetic acid were added. Experimental staining solutions were prepared in the following proportions of stock BS to stock FG—1:1, 2:1, 3:1, 1:2 and 1:3. Sections were brought to 50% alcohol and stained for 15, 20, 25 and 30 min in each of the five BS-FG mixtures, rinsed in 50% alcohol, then dehydrated in 70%, 95%, and absolute alcohol, 2 min each; cleared in xylene, and covered in balsam. The 2:1 (optimum proportion) combination of BS with FG, acting for 20 min, yielded 97% sex chromatin-positive nuclei in female material. If sections were stained in stock solution BS for 2 min, they could be differentiated by a 20 min treatment in the mordanting component of stock FG (without dye) to give a one-color stain. Such stains gave about the same percentage of sex chromatin-positive nuclei as those obtained by the regular two-color procedure. These modifications are simpler, more rapid, and yield results comparable to previously employed techniques.     

弱酸（盐）对植物乳杆菌耐酸性的影响

目的探讨弱酸（盐）对植物乳杆菌耐酸性的影响。方法在植物乳杆菌发酵过程中,添加50mmol／L乙酸、10mmol／L丙酸、20mmol／L正丁酸、50mmol／L乙酸钾及2mmol/L柠檬酸钾。结果添加剂量均可使植物乳杆菌耐酸性得到较大的提高,在pH2、37℃下90min,细胞残存率都较对照提高80倍以上,尤以乙酸（盐）、正丁酸为好,而三聚磷酸钾则对细胞耐酸性提高具有较小的作用,细胞残存率较对照约提高5倍。结论在发酵培养基中添加弱酸（乙酸、丙酸及正丁酸）或弱酸盐（乙酸钾、柠檬酸钾及三聚磷酸钾）均可不同程度地提高植物乳扦菌细胞耐酸性。     

Adaptation of Mallory's Trichrome Stain to Embryonic and Fetal Material

Based upon results of an investigation of the role of phosphotungstic acid in connective tissue staining, the Mallory trichrome stain was adapted to sequential application of all three dyes, thus making it usable on embryonic and fetal material. Ten to twelve day postconception mouse fetuses were formalin fixed and paraffin embedded. Staining was as follows: (1) 1% aqueous acid fuchsin for 5 min followed by not more than 30 sec in running tap water; (2) 2% aqueous phosphomolybdic acid (PMA) for 10 min followed by a 2 min running tap water wash; (3) staining in 0.5% aniline blue in 8% acetic acid for 10 min, followed consecutively by 30 sec in running tap water, 2% aqueous PMA for 2 min, and 30 sec in running tap water; (4) 2% orange G in 8% acetic acid for 5 min, and rinsing for 30 sec in running tap water. Dehydration in ethanol, t-butanol, acetone, or by blotting followed by 1:3 terpineol-xylene, clearing in xylene and mounting, completed the procedure. The 30 sec tap water rinses can optionally be replaced by 1-2 min in 8% acetic acid. Sections can be made redder by increasing acid fuchsin staining time, or increasing time in the first PMA; red can be decreased by decreasing staining time, increasing time of the 2 min tap water wash, or decreasing time in the first PMA. Blue or orange staining can be increased or decreased by varying staining times in these solutions. Sharper differentiation may be obtained by increasing the time in PMA.