银杏叶黄酮提取方法比较

比较不同溶剂提取银杏（ＧｉｎｋｇｏｂｉｌｏｂａＬ．）叶黄酮类化合物的提取效率,从成本效益角度考虑,以７０％乙醇作为提取溶剂更为有利。在分级沉淀中,黄酮含量与蛋白质含量呈正相关,在乙醇提取液中黄酮和蛋白质含量最高;蛋白质的存在有助于提高黄酮的溶解度。乙醇提取液用饱和（ＮＨ４）２ＳＯ４浓缩两次,可使醇相中的黄酮沉淀析出。根据试验结果,提出了银杏叶黄酮的优化提取方法。     

黄花败酱黄酮类化合物的提取与分析

用70％乙醇提取黄花败酱黄酮类化合物,得到粗黄酮,经聚酰胺纯化,得到精制黄酮。结果表明：黄花败酱干粉中总黄酮含量为2．35％,粗黄酮、精制黄酮中黄酮含量分别为8．81％和21．39％。黄花败黄酮类化合物主要是黄酮和黄酮醇两类,其中含有芦丁成分。     

PEG／（NH4）2SO4双水相体系在加杨叶总黄酮萃取分离中的应用

目的：寻找加杨叶粗提液中的总黄酮的有效方法。方法：利用双水相体系萃取分离、紫外分光光度法直接测定。结果：萃取分离加杨叶总黄酮的最佳双水相体系是25％PEG400与12％（NH4）2SO4,最佳萃取条件为：pH=9,NaCl的添加量为3％,粗提液3mL,温度25℃。结论：该方法的相对标准偏差（RSD）≤0．28％（n=5）,具有良好的精密度和选择性,为黄酮类化合物萃取分离的一种有效方法。     

迎春花植物茎叶中黄酮类物质初步研究

采用硝酸铝——亚硝酸钠比色法对迎春花茎叶内的黄酮类物质含量进行了初步测定,确定了总黄酮含量提取的适宜溶剂浓度和提取的适宜时间。结果表明,用60％甲醇溶剂提取5h总黄酮含量最高,茎杆中的含量为10．42mg/g DW,叶片中的含量为18．31mg／g DW。此外,还对迎春花叶提取液进行了各种黄酮定性颜色反应,初步确定其中的黄酮类物质主要为双氢黄酮类及查尔酮类。     

甘青铁线莲花中黄酮类化合物提取工艺探讨

对甘青铁线莲花中黄酮类物质的提取工艺进行研究。结果表明：在温度为80℃时,影响黄酮类化合物提取的因素顺序为提取时间〉乙醇浓度〉料液比。甘青铁线莲花中黄酮类物质的最佳提取条件为：当温度为80℃时,乙醇浓度80％、料液比1：30（g：mL）、回流时间为1．5h时提取最佳。在此条件下总黄酮的得率为1．86％。     

植物黄酮二氢杨梅素的提纯及结晶形态研究

显齿葡萄属植物富含黄酮物质。研究对显齿葡萄黄酮提取物二氢杨梅素的提纯及结晶态进行了初步探讨。结果表明:以水作为结晶溶剂进行多次重结晶,可有效去除植物黄酮提取物的杂质,总黄酮含量由原来的86%提高至96.5%。二氢杨梅素在水相中的结晶态多为针状结晶,水相保温结晶呈放射性棒状结晶。在pH4.5的条件下,其溶解度最低可获得较高的回收率。     

利用双水相萃取技术分离纯化尿激酶

通过研究双水相萃取系统的各种影响因素：乙醇／（NH4）2SO4的组成比例、pH值、无机盐的加入、粗酶的浓度等,探索以乙醇／（NH4）2SO4组成的双水相萃取体系纯化尿激酶的最佳条件。建立以乙醇／（NH4）2SO4组成的双水相萃取体系分离纯化尿激酶的新途径。结果表明：双水相萃取系统冰乙醇浓度为65％,（NH4）2SO4浓度为10．0％,pH8．0,酶加入量为30％,且不加入任何其他无机盐的条件下,尿激酶的纯化倍数可达到9．2倍,回收率最高达92％。     

Separation of Flavonoids from Bamboo Leaves by Aqueous Two-Phase Extraction

以竹叶黄酮水提溶液为原料,采用PEG(聚乙二醇)/(NH4 )2SO4双水相体系对竹叶黄酮进行萃取,考察了PEG平均相对分子质量、PEG质量分数、(NH4)2SO4质量分数、pH值、NaCl质量分数、原液质量分数、萃取温度等对双水相及竹叶黄酮萃取效果的影响.双水相萃取法提取竹叶黄酮的最优条件为:PEG 400 31％,(NH4)2 SO4 11％,pH3.9,NaCl 0.7％,原液51.5％,萃取温度20℃,在此条件下得到的竹叶黄酮萃取率为97.8％.结果说明,双水相萃取法操作简单方便,成本低,不会引起生物质失活或变性,适合于黄酮类化合物的萃取分离.     

响应面法优化白头翁总黄酮提取工艺

采用无水乙醇C2H5OH/硫酸铵(NH4)2SO4双水相体系分离白头翁中的黄酮。确定双水相体系组成为21%C2H5OH/22%(NH4)2SO4,通过单因素试验和Box-Benhnken实验设计探讨黄酮粗提液质量分数、NaCl质量分数和pH值对萃取效果的影响。确定最佳萃取条件为:黄酮粗提液质量分数12.5%,NaCl质量分数1.5%,pH 5.99,在此条件下,白头翁总黄酮主要分布在上相,萃取率可达73.6%。     

萃取破碎法提取酵母醇脱氢酶的研究

将双水相萃取同细胞破碎结合在一起,以水平搅拌式珠磨机为设备,以聚乙二醇和硫酸铵为成相体系,从酿酒酵母中以边破碎边萃取的方式提取醇脱氢酶。节省了萃取设备和时间,并利用双水相对蛋白质的保护作用提高了醇脱氢酶的活性。经过萃取破碎的酵母匀浆离心分相后,细胞碎片滞留在下相,90％以上的醇脱氢酶分配在上相,分配系数大于10,纯化倍数大于2。     

聚酰胺树脂纯化竹壳类黄酮工艺的研究

采用聚酰胺吸附树脂对竹笋壳黄酮类化合物分离纯化,确定了聚酰胺吸附树脂对竹笋壳黄酮分离纯化的最佳工艺条件:制备5mg/mL的竹笋壳黄酮提取液90mL,调节pH=5,用1.8mL/min的流速上样后,用160mL的去离子水冲洗大量杂质,随后用120mL的60%乙醇溶液洗脱120mL。在此条件下,竹笋壳黄酮的纯度为58.4%,与大孔树脂纯化方法相比,该方法更具有良好的分离纯化效果。     

大孔树脂分离纯化辣椒叶总黄酮的工艺研究

目的:筛选适合分离纯化辣椒叶总黄酮的一种大孔树脂,同时用响应面法进行优化得到最佳纯化工艺。方法:采用热回流法提取辣椒叶总黄酮,以吸附率和解吸率为考察指标,考察6种不同型号的大孔树脂(HPD100、HPD450、HPD600、HPD826、D101、AB-8)对辣椒叶总黄酮的吸附能力与解吸能力,确定最佳树脂。通过动态吸附解吸实验考察此树脂对辣椒叶总黄酮的最佳分离纯化工艺。结果:通过对辣椒叶总黄酮吸附分离性能的分析显示HPD600为最佳树脂,最优工艺为:上样浓度为10 mg/mL,上样量为10 mL,洗脱体积为4 BV,洗脱液流速为4 mL/min,洗脱液pH为7,依次用水、10%、30%乙醇冲洗树脂柱,50%乙醇为洗脱液。纯化后的黄酮纯度435.4 mg/g。结论:该方法简便,操作简单,对辣椒叶总黄酮的纯化效果较好。     

Three-phase partitioning as a rapid and efficient method for purification of invertase from tomato

Three-phase partitioning (TPP), a technique used in protein purification, was used to purify invertase from tomato (Lycopersicon esculentum). The method consists of simultaneous addition of ammonium sulfate and t-butanol to the crude enzyme extract in order to obtain the three phases. Different parameters (ammonium sulfate saturation, crude extract to t-butanol ratio and pH) essential for the extraction and purification of invertase were optimized to get highest purity fold and yield. It was seen that, 50% (w/v) ammonium sulfate saturation with 1:1 (v/v) ratio of crude extract to t-butanol at pH 4.5 gave 8.6-fold purification with 190% activity recovery of invertase in a single step. Finally, the purified enzyme was also characterized and the general biochemical properties were determined. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of enzyme showed considerable purification and its molecular weight was nearly found to be as 20 kDa. This work shows that, TPP is a simple, quick and economical technique for purification of invertases.     

Selective adsorption of flavonoid compounds from the leaf extract of Ginkgo bilobaL.

A simple purification method has been developed in which flavonoid compounds are selectively adsorbed onto a polycarboxyl ester resin (XAD-7) from methanol extract of ginkgo leaves. When 1.0 g dried gingko leaves was extracted with 100 ml of methanol, about 98% of total flavonoid compounds was recovered by selective adsorption. The pH did not affect the adsorption of flavonoids but at high pH the chemical structure of flavonoids was changed and the adsorption decreased to almost zero. As the solution polarity played a key role in the selective adsorption, the amount of water added to the methanol extract was critical for the recovery and loading of flavonoids. Using standard flavonoids, kaempferol and quercetin, the optimal water content was 80% and the recovery was 80% with 10 g of resin dosage/l.     

祁白术多糖提取工艺研究

以蒽酮-硫酸比色法测多糖含量,以正交优选工艺条件进行验证提取并加样测定回收率,结果显示：水提最佳条件为料液比1∶10、水浴100℃、恒温3 h,沉淀得率为48.41%,可溶性糖含量为43.83%,可溶性糖得率为21.22%;水提后醇沉条件为药液浓缩为1.5mL药液/g生药、醇沉浓度达到90%、4℃冰箱24h,醇沉得率为31.28%。水提法料液比、水提温度影响有显著性（P〈0.05）、醇沉法醇沉浓度影响有显著性（P〈0.05）。工艺验证实验平均得率31.55%,RSD=1.57%;加样回收率平均98.00%,以优选工艺方法提取、较稳定可行。     

Downstream processing of extracellular phytase from Aspergillus niger: Chromatography process vs. aqueous two phase extraction for its simultaneous partitioning and purification

The application of single step aqueous two-phase extraction (ATPE) for the downstream processing of phytase from Aspergillus niger NCIM 563, produced under solid state fermentation, has been studied and compared with the traditional multi-step procedure involving salt precipitation and column chromatography. High phytase recovery (98.5%) within a short time (3 h) and improved thermostability was attained by ATPE in comparison to 20% recovery in 96 h by chromatography process. The ATPE method, therefore, seems to be an interesting alternative for simultaneous partitioning and purification of phytase. The influence of system parameters; such as, phase forming salts, polymer molecular weight and system pH on the partitioning behavior of phytase was evaluated. The ATPE system consisting of combination of polyethylene glycol (PEG) 6000 and 8000 (10.5%) and sodium citrate (20.5%) resulted in one-sided partitioning of phytase in bottom phase with a purification factor of 2.5. This is the first report on phytase purification using liquid–liquid extraction and the results are likely to be beneficial in the poultry feed industry.     

Effect of nutritional factors on cellulase enzyme and microbial protein production by Aspergillus terreus and its evaluation

The biomass yield, cellulolytic activity, and protein recovery using Aspergillus terreus GN1 with alkali-treated sugarcane bagasse was studied using different levels (250-600 mg of N/L of broth) of organic and inorganic nitrogen sources. e.g., cattle urine, urea, cornsteep liquor, ammonium sulfate, ammonium nitrate, ammonium iron sulfate, ammonium chloride, and sodium nitrate. Among different levels of alkali-treated bagasse substrate concentrations (0.5-4.0% w/v) tested, 1.0% substrate yielded the highest crude protein content, protein recovery, and cellulolytic activity. The biomass recovery with 1.0% substrate ranged from 290-380 mg/500 mg bagasse substrate in a 50-mL broth with a nitrogen level of 250-600 mg of N/L in all the sources except ammonium iron sulfate, which yielded 402-439 mg/500 mg bagasse substrate. However, crude protein content of biomass obtained with an ammonium iron sulfate nitrogen source was the lowest. Cornsteep liquor nitrogen source at the rate of 600 mg of N/L yielded the maximum crude protein of 32.9%, protein recovery of 22.2 g/100 g of bagasse, and carboxymethyl cellulase and filter paper enzyme activities of 1.1 and 0.09 units/mL, among the organic and inorganic nitrogen sources studied. In general, the organic nitrogen sources and inorganic nonammonium nitrogen sources were utilized preferentially for protein production over the inorganic ammonium nitrogen sources. The fermentation time required under optimum cultural and nutritional conditions for A. terreus GN1 was also evaluated. The crude protein content of the biomass increased gradually up to the seventh day of fermentation, but the protein recovery rate was high up to two or three days. It was observed that the cellulose utilization rate increased after an initial lag of one day up to the third day and gradually increased further, which corresponded positively with protein content, biomass protein recovery, and cellulase enzyme activity. On the seventh day of fermentation, the crude protein content, biomass protein recovery, water-soluble carbohydrate, bagasse cellulose utilization, CMCase, and FPase activities were 32.8%, 20.1 g/100 g of bagasse, 6.2%, 82.7%, 1.0. and 0.08 U/mL, respectively. The final biomass recovered contained 32.8% crude protein content and had an in vitro rumen digestibility (IVRD) coefficient of 68.8%. The biomass contained almost all the essential and nonessential amino acids and was comparable with FAO reference protein. It is concluded that a fermentation time of 72 h gave a faster rate of protein production of 16.9 g/100 g of bagasse with 69.8% bagasse cellulose utilization with 76.0% IVRD. and contained almost all the essential and nonessential amino acids.     

双水相超声法提取桦褐孔菌三萜

通过单因素实验和正交实验对影响桦褐孔菌三萜提取的异丙醇体积浓度、硫酸铵质量浓度、料液比和超声时间等因素进行探讨,旨在建立桦褐孔菌Inonotus obliquus菌丝体三萜类化合物的提取工艺。结果表明,提取桦褐孔菌三萜的最佳条件为：异丙醇体积浓度40%,硫酸铵质量浓度0.125g/mL,料液比（W/V）0.9:1,超声时间为35min,三萜提取率为6.18%,提取效率明显高于常规超声波提取法（5.38%）。利用该方法获得的三萜具有较强清除自由基的能力。通过正交实验获得的桦褐孔菌三萜的提取工艺是一种经济、有效的方法。     

宁夏枸杞叶总黄酮提取和纯化方法的优化

采用L9(3⁴)正交设计,以黄酮含量为指标,确定的宁夏枸杞叶总黄酮的最佳超声提取方法为: 30倍70%乙醇超声提取50 min,超声功率为250 W;纯化方法条件为: 5倍柱体积70%乙醇洗脱,浓度为4 mg/mL、pH值5.0的上样液,上样速度和洗脱流速均为1 mL/min。并以吸附率、解吸率、回收率等作为考察参数,对提取和纯化方法进行了验证。实验结果表明,该方法简便节时、易操作且毒害小,各项变异系数低。     

面包树果实凝集素的提取纯化及理化性质分析

建立面包树果实凝集素(frutalin,FTL)的提取纯化方案,并对FTL纯品进行部分理化性质分析。本试验以新鲜的面包树果实籽为材料,经Tris-HCl缓冲液浸提、过滤、硫酸铵沉淀和阳离子交换层析后超滤浓缩得FTL纯品,最后用纯品开展了糖抑制,热稳定性,pH稳定性和金属离子耐受性等试验。提取优化得到的最佳条件为:料液比1∶2(g:m L),浸提时间2 h,浸提温度50℃,硫酸铵饱和度70%,沉淀时间4 h。经阳离子交换层析后FTL回收率为22%。研究结果表明,FTL是一种热稳定性凝集素,在温度不超过60℃时,其凝血活性不受影响,并且不依赖于金属离子来发挥其凝血活性。本研究建立了一个简单高效的FTL分离纯化方案,并对FTL纯品做了部分理化性质研究,为FTL可能的生物医学应用提供研究基础。