箭叶淫羊藿中5种黄酮类化合物的反相色谱分离制备

用半制备型反相高效液相色谱(RPLC)对箭叶淫羊藿提取液中的5种主要黄酮类化合物进行了分离制备,优化了分离条件。每次进提取液35mL,经一步RPLC便可得到纯度均大于95％的化合物Ⅰ、Ⅱ、Ⅲ和Ⅴ,经过10次制备,共制得93mg Ⅰ、71mgⅡ、296mgⅢ和487mg Ⅴ。而经一步纯化得到的化合物Ⅳ的纯度较低,再经第二步RPLC纯化后可使其纯度大于95％,最后得到64mgⅣ。经波谱分析鉴定所得的5种化合物分别为hexandraside F、朝藿定A、朝藿定B、朝藿定C及淫羊藿甙,均为8-异戊烯基黄酮类化合物,其中hexandraside F是首次从淫羊藿属植物中分离得到的。     

反相高效液相色谱法分离制备蜂毒肽类似物

应用高效制备液相色谱法，对5种合成的蜂毒肽类似物分离制备。当用极性较强的洗脱液做流动相时，主峰的保留时间短，且主峰和前后的杂质峰不能很好的分开；随着洗脱液极性减弱至某一值时，主峰和杂质峰的保留时间均向后延长，且时间间隔加大，可以成功地对多肽样品进行分离制备。有多肽分子中各氨基酸保留常数加和值的方法可以预测不同多肽的保留时间，为选择分离纯化多肽所需的流动相提供了参考作用。经半制备分离纯化后的产物用分析型RP－HPLC测定达到了很高的纯度，氨基酸分析结果表明得到了所需的肽段，可以用于下一步的研究工作。     

高速逆流色谱在分离纯化木蝴蝶活性成分中的线性放大

利用高速逆流色谱分离纯化中草药木蝴蝶乙酸乙酯粗提物中的黄酮类活性成分,并将分离规模从分析型线性放大到制备型,以获得大量的活性成分,为进一步的药物筛选提供物质基础。实验在分析型高速逆流色谱上对分离参数进行了系统优化,并将优化条件放大到制备型高速逆流色谱上对911.6 mg木蝴蝶乙酸乙酯粗提物进行分离,得到5种化合物,经高效液相色谱、电喷雾电离质谱和核磁共振氢谱、碳谱分析鉴定,分别为白杨素(160.9 mg,纯度为97.3%)、黄芩素(130.4 mg,纯度为97.6%)、黄芩素-7-O-葡萄糖苷(314.0 mg,纯度为98.3%)、黄芩素-7-O-双葡萄糖苷(179.1 mg,纯度为99.2%)和一种新的白杨素双葡萄糖苷(21.7 mg,纯度为98.8%)。该放大过程不仅将处理量提高了53倍,还保持了在分析型设备上的分离度和分离时间。该工作为天然产物的研究提供了一个高效的分离纯化方法。     

胰岛素反相制备色谱的方法开发

以胰岛素反相制备色谱方法的开发和优化为目标,通过考察色谱保留参数、峰展宽及样品流出曲线的浓度分布等色谱参数,对流动相梯度、色谱填料、载样量等色谱条件进行了优化,并建立了胰岛素制备色谱峰参数的描述方法。结果表明,所建立的方法可快速筛选出最适于胰岛素分离的色谱条件(包括流动相梯度及分离填料),即流动相中的强洗脱溶剂(有机相)需采取缓梯度窄区间的变化条件,筛选出的分离填料需具备峰向两侧展宽且展宽程度较小、样品最高浓度居中分布的特点。将方法用于实际胰岛素粗品的纯化制备,获得了杂质去除效果好、胰岛素纯度高的产品。该法为胰岛素反相色谱纯化制备方法的快速建立提供了指导,具有较强的实用价值,同时为发展大分子化合物的制备色谱方法提供了参考。     

离线二维反相液相色谱/超临界流体色谱在瓜蒌子分离中的应用

发展了离线二维反相液相色谱/超临界流体色谱(2D RPLC/SFC)分离瓜蒌子的方法。实验在第一维采用反相色谱,按色谱峰收集从瓜蒌子样品中制备得到的12个组分(F_1~F_(12)),并将得到的组分在第二维使用SFC分离。这些组分在RPLC和SFC的分离对比说明,该二维方法具有良好的分离正交性,可至少检测到150个色谱峰,对于解决结构相似物质的分离、微量成分的富集表现出了明显的优势。SFC方法采用了乙醇-正己烷(3∶7,v/v)的混合溶剂作为改性剂,既提供了适当的洗脱能力,也保证了在上样量增加时满足样品溶解的要求。此二维分离体系可放大到制备水平用于化合物的制备,为瓜蒌子化学成分的纯化制备提供技术支持,为其物质基础研究提供参考。     

酪蛋白多肽的制备和色谱分离方法

为了得到低成本的多肽,本文利用胰蛋白酶对酪蛋白进行了充分的酶解。采用分析级反相高效液相色谱-电喷雾质谱联用技术(RP-HPLC/ESI-MS)分析了酶解产物各组分的组成,并通过改变流动相的梯度洗脱程序,优化了分析级色谱条件以充分分离相对含量较高的多肽组分;将优化的分析级色谱条件直接放大到制备级RP-HPLC中,在程序控制下通过紫外吸收信号结合ESI-MS信号共同引导实现了多肽的全自动化分离和收集。整个过程方便快捷,经过这样一个单一的分离步骤,得到了多个纯度较高的多肽。除此之外,本文还考察了流动相的酸碱性、柱上样量等因素对该体系制备级分离的影响,并对一次分离中分辨率不好的亲水性多肽混合物进行了二次分离,得到了多个新的多肽。本文建立的多肽制备方法为多肽和多肽材料的广泛应用提供了一种选择。     

分析型色谱饼对人血清白蛋白的快速纯化

采用分析型色谱饼对标准蛋白混合物进行了分离,结果表明装填有小颗粒填料的色谱饼在高流速条件下仍然具有良好的分离能力。在较大流速(5 mL/min)条件下,在10 min内对人血清白蛋白样品进行了快速纯化,其纯化后的人血清白蛋白的纯度大于85%,回收率为65%,说明分析型色谱饼可以用于快速分离纯化生物大分子。     

纳升液相色谱-高分辨串联质谱研究冻存条件对唾液多肽组的影响

唾液多肽组学为疾病相关的生物标记物研究提供了新方法,但冻存条件对分析结果的影响并不清楚。本研究采用氧化石墨烯-磷酸镧纳米复合材料分离富集唾液多肽,利用纳升液相色谱-高分辨串联质谱技术,考察唾液样品分别置于-80℃与-20℃冻存6个月后对唾液多肽组的影响。结果表明,在-80℃冻存条件下的唾液样品中,共鉴定出归属于33种蛋白的429条肽段;在-20℃冻存条件下的唾液样品中,鉴定出595条肽段,对应31种蛋白。实验结果表明,相比于-80℃,唾液置于-20℃条件下的新增加肽段主要来源于已有肽段的降解,并且唾液中的蛋白质也发生了一定降解。本研究在肽段序列水平上考察了冻存条件对多肽的影响,结果表明,-20℃冻存条件不适合长期保存用于多肽组分析的唾液样品。本研究结果可为相关医学研究提供借鉴。     

超大孔离子交换制备色谱分离纯化高活性凝血因子VIII

建立了一条从人血浆中分离高活性凝血因子VIII(FVIII)的纯化工艺。基于FVIII和介质孔径的尺度比及其对蛋白质活性影响的分析,设计了以超大孔离子交换制备色谱为核心步骤的新型分离纯化工艺。分别进行超大孔离子交换色谱与传统离子交换色谱的条件优化,并对优化工艺所得产品进行了活性检测(底物显色法)和纯度检测(高效凝胶过滤和凝胶电泳)。结果表明,超大孔介质结构不但可以有效地保护蛋白质大分子结构,而且能够大幅度地提高制备色谱的传质速率,从而得到具有高凝血活性的FVIII产品。FVIII在超大孔制备色谱过程中的回收率(85%)比传统离子交换制备色谱高4～5倍,产品比活高达154 IU/mg。此外,还研究了超大孔介质的再生程序,采用5个柱体积的1 mol/L NaOH低流速清洗色谱柱,保证了色谱工艺的稳定性。本纯化工艺步骤简单,重现性好,易于放大生产。     

单分散交联聚甲基丙烯酸环氧丙酯树脂的制备及亲合纯化伴刀豆球蛋白-A

采用一步种子溶胀聚合法制备了颗粒呈单分散的交联聚甲基丙烯酸环氧丙南树脂，对其环氧基的组成比进行了表征，并以氨基葡萄糖为配基，首次制备了纯化粗品伴刀豆球蛋白-A(Ⅲ）(Con-A，Ⅲ)的聚合物基质的高效亲合色谱柱。配基在树脂上的键合量为8．2mg／g，对纯化后的Con-A（Ⅲ）的吸附量为13．4mg／g。使用该亲合色谱介质成功地从粗品Con-A中快速纯化了Con-A，电泳分析显示为一个主要的谱带，纯度从15％提高到95％。     

One-step purification of epigallocatechin gallate from crude green tea extracts by mixed-mode adsorption chromatography on highly cross-linked agarose media

(-)-Epigallocatechin gallate (EGCG) was purified in one step from a green tea polyphenol (GTP) crude extract by adsorption chromatography on a Superose 12 HR 10/30 column. The mobile phase used was a mixture of acetonitrile and water with an optimum mobile phase compositions regarding purity, recovery and separation time of 78/22 (v/v). Maximum practical sample loading was 100 mg GTP per run (corresponding to 4.2 mg/ml Superose). An EGCG purity of 99% with recoveries in the range 60-65% was achieved in one step directly from the crude GTP extract. Full column regeneration was obtained using solvents in the following order: 0.5 M NaOH, distilled water and 30% acetic acid.     

Orthogonal test design for optimization of supercritical fluid extraction of daphnoretin, 7-methoxy-daphnoretin and 1,5-diphenyl-1-pentanone from Stellera chamaejasme L. and subsequent isolation by high-speed counter-current chromatography

Supercritical fluid extraction (SFE) of daphnoretin, 7-methoxy-daphnoretin and 1,5-diphenyl-1- pentanone from Stellera chamaejasme L. was performed. An orthogonal L9 (3)4 test design was applied to select the optimum extraction parameters including pressure, temperature, modifier and sample particle size on yield using an analytical-scale SFE system. The process was then scaled up by 100 times using a preparative SFE system under the optimized conditions of 25 MPa of pressure, 45 degrees C of temperature, 40-60 mesh of sample particle size and modified CO2 with 20% methanol. The yield of the crude extract from preparative SFE was 2.65%, which contained daphnoretin 25.2%, 7-methoxy-daphnoretin 22.8% and 1,5-diphenyl-1-pentanone 21.1%, respectively. Then the crude extract was successfully isolated and separated by preparative high-speed counter-current chromatography (HSCCC) with a two-phase solvent system composed of n-hexane-ethyl acetate-methanol-water (10:13:13:10, v/v) by increasing the flow-rate of the mobile phase stepwise from 1.0 to 2.0 ml/min after 90 min. The target compounds isolated and purified by HSCCC were analyzed by high-performance liquid chromatography (HPLC). The separation produced total of 69.2mg of daphnoretin at 99.2% purity, 63.4 mg of 7-methoxy-daphnoretin at 98.7% purity and 58.3 mg of 1,5-diphenyl-1-pentanone at 98.1% purity from 300 mg of the crude extract in one-step separation. The recoveries of daphnoretin, 7-methoxy-daphnoretin and 1,5-diphenyl-1-pentanone were 90.8, 91.5 and 90.4%, respectively, in HSCCC isolation step and the chemical structure identification was carried out by MS, 1H NMR and 13C NMR.     

Isolation and purification of arctigenin from Fructus Arctii by enzymatic hydrolysis combined with high‐speed counter‐current chromatography

Enzymatic hydrolysis pretreatment combined with high‐speed counter‐current chromatography for the transformation and isolation of arctigenin from Fructus Arctii was successfully developed. In the first step, the extract solution of Fructus Arctii was enzymatic hydrolyzed by β‐glucosidase. The optimal hydrolysis conditions were 40°C, pH 5.0, 24 h of hydrolysis time, and 1.25 mg/mL β‐glucosidase concentration. Under these conditions, the content of arctigenin was transformed from 2.60 to 12.59 mg/g. In the second step, arctigenin in the hydrolysis products was separated and purified by high‐speed counter‐current chromatography with a two‐phase solvent system composed of petroleum ether/ethyl acetate/methanol/water (10:25:15:20, v/v), and the fraction was analyzed by HPLC, ESI‐MS, and ¹H NMR spectroscopy. Finally, 102 mg of arctigenin with a purity of 98.9% was obtained in a one‐step separation from 200 mg of hydrolyzed sample.     

Free flow electrophoresis as a method for the purification of enzymes from E. coli cell extract

The application of the four techniques of free flow electrophoresis (zone electrophoresis, isotachophoresis, isoelectric focusing and field step electrophoresis) for the purification of proteins from a complex protein mixture was investigated. For this purpose alpha-amylase (EC 3.2.1.1) from Aspergillus oryzae was added and reisolated from E. coli cell extract. The chosen enzyme and the biological extract are models for many industrial separation problems. In optimized experiments purity, purification factor, yield, throughput and efficiency were calculated. The best results were obtained with field step electrophoresis in combination with zone electrophoresis. High purity (0.82 mg enzyme/mg total protein) and high throughput (111 mL sample/h) were achieved using this technique. Field step electrophoresis gave the best throughput (330 mL sample/h), but low purity (0.63 mg enzyme/mg total protein). This technique can also be used for a simple concentration of the sample. With zone electrophoresis a purity of more than 0.95 mg enzyme/mg total protein was obtained, which was the best of all techniques. However, the enzyme concentration was decreased due to dilution with buffer solution after the separation. Isotachophoresis was the most difficult technique, combined with a relatively low recovery of 31% of the enzyme activity. In a purification scheme, free flow electrophoresis is able to substitute one or even several chromatography steps with a negligible loss of biological activity.     

Elution-extrusion counter-current chromatography separation of five bioactive compounds from Dendrobium chrysototxum Lindl

The elution-extrusion counter-current chromatography (EECCC) method was firstly developed by Berthod in 2003 and has been used in natural products separation in recent years. The advantages of this method have been well documented such as reducing the separation time and solvent consumption. In the EECCC method, the time point of the extrusion step is very important during the whole separation process as it directly affects the resolutions, separation time and solvent consumption. However, how to choose a suitable time point to perform the extrusion step without decreasing the resolution has not been studied yet. In the present study, a strategy for systematically calculating the time point for extrusion was developed in theory and five bioactive compounds from the extract of Dendrobium chrysototxum Lindl. were separated and compared using normal CCC and EECCC method. Our results demonstrated that the accurate time point to perform the extrusion could be calculated and reduced both separation time and solvent consumption without losing separation performance. Using this EECCC method, five bioactive compounds were separated and purified with high purity. The separation time and solvent consumption were decreased from 200 min to 100 min and 5-2.5L during the separation process while the resolutions were still acceptable. Finally, 63 mg, 48 mg, 97 mg, 162 mg and 43 mg of hydroxyl phenanthrenes and bibenzyls with the purity of 98.7%, 98.0%, 98.2%, 99.0% and 98.7%, respectively were isolated from 1.2 g crude extract of D. chrysototxum Lindl. initially purified by column chromatography in one step separation. The purities of compounds were determined by HPLC. Their structures were identified by electrospray ionization-mass spectrometry (ESI-MS) and NMR.     

利用高效弱阴离子交换色谱法纯化超氧化物歧化酶

利用高软弱阴离子交换色谱法简化了超氧化物歧化酶（ＳＯＤ）的纯化手续。在丙酮沉淀后,仅用一步色谱分离就能使来自牛血的Ｃｕ,Ｚｎ－ＳＯＤ达到电泳纯,活性回收率为８６．４％,比活为７７１１Ｕ／ｍｇ,纯化倍数提高至５２倍。此外,详尽讨论了色谱分离的条件。     

Efficient new method for extraction and isolation of three flavonoids from Patrinia villosa Juss. by supercritical fluid extraction and high-speed counter-current chromatography

Supercritical fluid extraction (SFE) of orotinin, orotinin-5-methyl ether and licoagrochalcone B from Patrinia villosa was performed. The optimization of parameters including pressure, temperature, modifier and sample particle size on yield was carried out using an analytical-scale SFE system. The process was then scaled up by 100 times using a preparative SFE system under the optimized conditions of 25 MPa, 45 degrees C, a sample particle size 40-60 mesh and modified CO2 with 20% methanol. The yield of the preparative SFE was 2.82% (crude extract I) and the combined yield of orotinin, orotinin-5-methyl ether and licoagrochalcone B was 0.82 mg/g of dry sample mass. Then the crude extract I was re-dissolved in methanol and methanol soluble fraction (crude extract II, 0.17%) was obtained, which was successfully isolated and separated by a preparative high-speed counter-current chromatography (HSCCC) with a two-phase solvent system composed of n-hexane-ethyl acetate-methanol-water (5:6:6:6, v/v/v/v) by increasing the flow-rate of the mobile phase stepwise from 1.0 to 2.0 ml/min after 3 h. The target compounds isolated and purified by HSCCC were analyzed by high performance liquid chromatography. The separation produced total of 38.2 mg of orotinin at 99.2% purity, 19.8 mg of orotinin-5-methyl ether at 98.5% purity and 21.5 mg of licoagrochalcone B at 97.6% purity from 400 mg of the crude extract in a one-step separation. The recoveries of orotinin, orotinin-5-methyl ether and licoagrochalcone B were 91.1, 91.6 and 90.3%, respectively, and the chemical structure identification was carried out by UV, IR, MS, 1H NMR and 13C NMR.     

Optimization of parameters of high-performance displacement chromatography for separation of soybean phosphatidylcholine and phosphatidylethanolamine

Hundred milligrams of soybean phospholipids were successfully separated by using high-performance displacement chromatography (HPDC) on a 150mm x 4.6mm analytical silica column (3-5 microm packings) with dichloromethane-methanol (9:1, v/v) as carrier and ethanolamine as displacer. From the viewpoint of preparative separation, the effects of loading amount, concentration and flow-rate of displacer on separation efficiency were investigated using throughput and recovery as indices. The parameters were optimized by orthogonal test design and statistical analysis method. Under the optimum conditions, namely displacer concentration being 167 mM, the flow-rate of displacer at 0.2 ml/min and concentration of sample being 211 mg/ml (factual loading amount 211 mg/ml x 0.7 ml = 148 mg), the purity, throughput and recovery of obtained soybean phosphatidylethanolamine (PE) and phosphatidylcholine (PC) were 80.2%, 65.7 mg/h, 70.9% and 90.5%, 272.6 mg/h, 88.3%, respectively. In addition, selections of regenerant and appropriate regeneration condition were also studied.     

Isolation and purification of recombinant human plasminogen Kringle 5 by liquid chromatography and ammonium sulfate salting‐out

In this work, a novel method was established to isolate and purify Human plasminogen Kringle 5 (HPK5) as a histidine‐tagged fusion protein expressed in Escherichia coli BL21 (DE3). This method consisted of sample extraction using a Ni‐chelated Sepharose Fast‐Flow affinity column, ammonium sulfate salting‐out and Sephadex G‐75 size‐exclusion column in turn. The purity analysis by SDS–PAGE, high‐performance size‐exclusion and reversed‐phase chromatographies showed that the obtained recombinant fusion HPK5 was homogeneous and its purity was higher than 96%; the activity analysis by chorioallantoic membrane model of chicken embryos revealed that the purified recombinant HPK5 exhibited an obvious anti‐angiogenic activity under the effective range of 5.0–25.0 µg/mL. Through this procedure, about 19 mg purified recombinant fusion HPK5 can be obtained from 1 L of original fermentation solution. Approximate 32% of the total recombinant fusion HPK5 can be captured and the total yield was approximately 11%. Copyright © 2013 John Wiley & Sons, Ltd.