反相高效液相色谱法制备纯化大豆异黄酮糖苷

利用制备高效液相色谱法从大豆总异黄酮提取物中制备出了3种大豆异黄酮糖苷。在Nova-Pak HR C18色谱柱(100 mm×25 mm i.d.,6 μm)上,以甲醇-体积分数为0.1%的乙酸水溶液(体积比为23∶77)为流动相,流速为20 mL/min,采用 等度洗脱方式,制备了3种大豆异黄酮糖苷,经质谱分析,确认它们分别为大豆苷、黄豆苷和染料木苷。高效液相色谱分析 表明,所制备的3种化合物的纯度均达到了99%以上。     

Purification of compounds from Lignum Dalbergia Odorifera using two-dimensional preparative chromatography with Click oligo (ethylene glycol) and C18 column

Purification of compounds from traditional Chinese medicines (TCMs) is an important task for understanding the chemical composition of TCMs. However, it is difficult to obtain compounds with high enough purity for identification by NMR due to the complexity of TCMs in chemical composition. In this study, a two‐dimensional purification method based on a Click oligo (ethylene glycol) column and a C18 column was developed to realize an orthogonal separation in preparative level for purifying compounds efficiently. The first dimensional preparation was performed on a Click oligo (ethylene glycol) column to simplify the sample into the fractions with good separation repeatability. On the first dimension, 7.2 g sample was separated into 11 fractions with a recovery of 86% within 6 h. A C18 column was taken as the second dimension to realize the high‐performance separation and rapid preparation from the fractions collected from the first dimension. Eight compounds in fraction 6 and 2 compounds in fraction 8 were isolated and identified after optimizing the separation and collection parameters. This method is a high‐efficient and orthogonal preparation method to improve the separation of a complex sample and increase the purity of the compounds, which benefits from the application of novel materials in the preparation and purification.     

Determination of the residue of quizalofop-p-tefuryl in soybean by HPLC

A HPLC method was developed for the analysis of quizalofop-P-tefurylof in soybean. The samples were extracted with methanol-water (volume ratio), The extracts were cleaned up with a column of silica gel. The final residue was detected by HPLC, using a UV detector. The recoveries from the analytical method for soybean were 84.32%–89.25%. Variable coefficients were 0.49%∼1.51%. This method proved to be simple, reliable and accurate. __________ Translated from Chinese Journal of Chromatography, 2005, 23(2)(in Chinese)     

Analysis of soybean protein-derived peptides and the effect of cultivar, environmental conditions, and processing on lunasin concentration in soybean and soy products

Soybean, an important source of food proteins, has received increasing interest from the public because of its reported health benefits. These health benefits are attributed to its components, including isoflavones, saponins, proteins, and peptides. Lunasin, Bowman-Birk inhibitor, lectin, and beta-conglycinin are some of the biologically active peptides and proteins found in soybean. This article provides a comprehensive review on the recently used techniques in the analysis and characterization of food bioactive peptides, with emphasis on soybean peptides. The methods used to isolate and purify lunasin from defatted soybean flour were ion-exchange chromatography, ultrafiltration, and gel filtration chromatography. The identity of lunasin was established by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, Western blot, matrix-assisted laser desorption ionization-time of flight, and liquid chromatography. The results on the effect of soybean cultivar and environmental factors on lunasin concentration are also reported. The highest lunasin concentration, 11.7 +/- 0.3 mg/g flour, was found in Loda soybean cultivar grown at 23 degrees C; the lowest concentration, 5.4 +/- 0.4 mg/g flour, was found in Imari soybean cultivar grown at 28 degrees C. Lunasin concentration was affected by cultivar-temperature, cultivar-soil moisture, and cultivar-temperature-soil moisture interactions. The variation on lunasin concentration suggests that its content can be improved by breeding, and by optimization of growing conditions. In summary, bioactive peptides can be accurately identified and quantified by using different techniques and conditions. In addition, lunasin concentration in soybean depends mainly on cultivar and to some extent on environmental factors, particularly temperature. Lunasin concentration in soy products was also affected by processing conditions.     

超声提取正相高效液相色谱法测定大豆及大豆油中的磷酸甘油酯

建立了超声提取-固相萃取纯化/正相高效液相色谱测定大豆及大豆油中磷脂酰胆碱(PC)、磷脂酰乙醇胺(PE)、磷脂酰肌醇(PI)的方法。考察了提取溶剂、超声功率、超声时间、提取温度及净化方式的影响,并研究了不同色谱固定相对磷酸甘油酯分离效果的影响。优化的实验条件为:以氯仿-甲醇(2∶1,体积比)为提取溶剂,1 500 W功率超声提取30 min;氨基固相萃取柱为纯化小柱;正己烷-异丙醇-1%HAc(8∶8∶1,体积比)为流动相。在该条件下,PC、PE、PI的线性范围分别为0.08～8.00、0.15～15.00、0.30～20.00 g.L-1,定量下限分别为0.021、0.050、0.060 g.L-1,检出限在8～23 mg.L-1之间,其在大豆和大豆油中的回收率为85%～108%。日内与日间精密度分别不大于4.7%和8.6%。     

Chemical fingerprint analysis and quantitative determination of steroidal compounds from Dioscorea villosa,Dioscorea species and dietary supplements using UHPLC‐ELSD

Ultra high‐performance liquid chromatography (UHPLC) with evaporative light scattering detection was used for the quantification of steroidal saponins and diosgenin from the rhizomes or tubers of various Dioscorea species and dietary supplements that were purported to contain Dioscorea. The analysis was performed on an Acquity UPLC? system with an UPLC? BEH Shield RP₁₈ column using a gradient elution with water and acetonitrile. Owing to their low UV absorption, the steroidal saponins were observed by evaporative light scattering detection. The 12 compounds could be separated within 15 min using the developed UHPLC method with detection limits of 5–12 µg/mL with 2 μL injection volume. The analytical method was validated for linearity, repeatability, accuracy, limits of detection and limits of quantification. The relative standard deviations for intra‐ and inter‐day experiments were <3.1%, and the recovery efficiency was 97–101%. The total content of standard compounds was found to be in the ranges 0.01–14.5% and 0.9–28.6 mg daily intake for dry plant materials and solid commercial preparations, respectively. UHPLC–mass spectrometry with a quadrupole mass analyzer and ESI source was used only for confirmation of the identity of the various saponins. The developed method is simple, rapid and especially suitable for quality control analysis of commercial products. Copyright © 2013 John Wiley & Sons, Ltd.     

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.     

大豆磷脂的高效液相色谱分析

采用正相高效液相色谱法,梯度洗脱程序和蒸发光散射检测器对大豆磷脂组成进行分析,在15min内将大豆膦脂中4种重要组分：卵磷脂,脑磷脂,肌醇磷脂和磷脂酸与其它组分完全分离,用外标法对这4种重要成分进行定量,线性范围为0．2－5．8g/L,回收率为96．7－100．8％;相对标准偏差为0．82％－1．34％,方法用于实际样品测定,获得满意的结果。     

亲水/反相二维色谱法制备桔梗中的三萜皂苷

建立了亲水/反相二维色谱用于制备桔梗中三萜皂苷单体的方法。桔梗经水煮醇沉、反相和亲水两种模式的固相萃取后得到三萜皂苷类组分。选定XAmide色谱柱（150 mm×20 mm,5 μm）,以乙腈和水为流动相,在亲水色谱模式下进行组分制备。选择时间触发模式,以1 min为单位进行馏分收集,得到6~25 min之间的20个三萜皂苷精细组分。以第18个馏分（JG23）为例,在反相色谱模式下采用Atlantis Prep T3色谱柱（100 mm×30 mm,5 μm）制备,得到两个单体化合物。通过质谱和核磁共振对其进行定性,确定分别为deapi-platycoside E和platycoside E。实验结果表明,该制备方法具有好的正交选择性,对于复杂样品中三萜皂苷类化合物的分离纯化有一定的借鉴意义。     

Optimization of a chromatographic method for the gram-scale preparative fractionation of soybean phospholipids

Summary To enable the study of the functional properties of pure soybean phospholipids, a chromatographic method was developed for the preparative fractionation of soybean lecithin. A coarse and irregularly shaped silica gel was used as the stationary phase, whereas the mobile phase consisted of three mixtures of hexane, 2-propanol and water of increasing polarity. These solvents were included in a step gradient, formed by an isocratic pump connected to a solvent changer. To reduce solvent consumption, the procedure was optimised using a method development column. The solvent program and the sample load were shown to affect mainly the purity and recovery of phosphatidylinositol.     

Purification of saponins from leaves of Panax notoginseng using preparative two-dimensional reversed-phase liquid chromatography/hydrophilic interaction chromatography

Saponins are widely distributed in the plant kingdom and have been shown to be active components of many medicinal herbs. In this study, a two-dimensional purification method based on reversed-phase liquid chromatography coupled with hydrophilic interaction liquid chromatography was successfully applied to purify saponins from leaves of Panax notoginseng. Nine saponin reference standards were used to test the separation modes and columns. The standards could not be resolved using C₁₈ columns owing to their limited polar selectivity. However, they were completely separated on a XAmide column in hydrophilic interaction liquid chromatography mode, including two pairs of standards that were coeluted on a C₁₈ column. The elution order of the standards on the two columns was sufficiently different, with a correlation coefficient between retention times on the C₁₈ and XAmide columns of 0.0126, indicating good column orthogonality. Therefore, the first-dimension preparation was performed on a C₁₈ column, followed by a XAmide column that was used to separate the fractions in the second dimension. Fifty-four fractions were prepared in the first dimension, with 25 fractions rich in saponins. Eight saponins, including two pairs of isomeric saponins and one new saponin, were isolated and identified from three representative fractions. This procedure was shown to be an effective approach for the preparative isolation and purification of saponins from leaves of P. notoginseng. Moreover, this method could possibly be employed in the purification of low-content and novel active saponins from natural products.

Analysis of ginseng root and leaf by multiple columns and detections liquid chromatography

Abstract

A multiple columns and detections liquid chromatography system, including size exclusion chromatography (SEC) and reversed phase liquid chromatography (RPLC), for the analysis of macromolecules and micromolecules in ginseng root and leaf was developed. The columns were connected by two switching valves. Macromolecules were separated on a SEC column (TSK gel SuperMultipore PW-H column, 6?mm× 150?mm, 8?μm) by isocratic elution of 50?mM ammonium acetate aqueous solution, 0.3?mL/min of flow rate and detected by evaporative light scattering detection (ELSD). Micromolecules were analyzed on a Poroshell RP column (Agilent Poroshell 120?SB-Aq column, 4.6?mm × 50?mm, 2.7 µm) with gradient elution of water and acetonitrile, 0.6?mL/min of flow rate and detected by ultraviolet detection (UV). As a result, in the macromolecules chromatogram of ginseng root sample showed two main peaks while only one major peak for ginseng leaf. For micromolecules analysis, 17 compounds (3 nucleosides + 14 saponins) and 17 compounds (3 nucleosides + 1 flavonoid + 13 saponins) were found in ginseng root and leaf, respectively. The developed method is helpful for the quality evaluation of ginseng root and leaf.     

Single-Step Preparative Extraction of Artemisinin from Artemisia annua by Charcoal Column Chromatography

Activated charcoal column chromatography was successfully applied for preparative extraction of artemisinin with high-purity from Artemisia annua L. in one single run for the first time in this study. The adsorption kinetics study showed that powdery activated charcoal had high adsorption speed for artemisinin. The experimental adsorption data fitted well using the Langmuir adsorption model. The optimal parameters for the extraction of artemisinin were obtained using a column packed with activated charcoal: the loading amount, 1 g extract/5 g activated charcoal; the elution mode, CH₂Cl₂?CMeOH (2:5, v/v) for 5 BV (bed volume) after the removal of some impurities with CH₂Cl₂?CMeOH (1:10, v/v). With this optimized condition, artemisinin was finally obtained with purity at 95.2% and the recovery at 72.3%. The developed technique would provide a feasible large-scale method for the extraction of artemisinin in pharmaceutical industry.     

Preparative separation of minor saponins from Platycodi Radix by high-speed counter-current chromatography

Platycosides (PSs), the saponins found in the root of Platycodon grandiflorum (Jacq.) A. DC. (Platycodi Radix), are typically composed of oleanene backbones with two side chains; one is a 3-O-glucose linked by a glycosidic bond, and the other is a 28-O-arabinose-rhamnose-xylose-apiose linked by an ester bond. Minor saponins, acetylated isomers of the major saponin on either the 2' or 3' position of rhamnose, were isolated from Platycodi Radix using a multi-step process including high-speed counter-current chromatography (HSCCC) and preparative reversed-phase high-performance liquid chromatography (RP-HPLC). After the separation of the major components, the enriched minor saponin fraction was used for this study. A two-phase solvent system consisting of chloroform-methanol-isopropanol-water (3:2:2:3, v/v) was used for HSCCC. HSCCC separation of the enriched minor saponin fraction yielded 2'-O-acetylplatycodin D, 3'-O-acetylpolygalacin D, 2'-O-acetylpolygalacin and a mixture of 3'-O-acetylplatycodin D and polygalacin D. The mixture fraction from HSCCC separation was further purified by preparative RP-HPLC, giving 3'-O-acetylplatycodin D and polygalacin D at a purity of over 98.9%. The developed method provides the preparative and rapid separation of minor saponins in the crude extract of Platycodi Radix. To the best of our knowledge, this is the first on the separation of acetylated PSs by HSCCC.     

Simultaneous quantification of both triterpenoid and steroidal saponins in various Yunnan Baiyao preparations using HPLC–UV and HPLC–MS

Yunnan Baiyao (YNBY) is one of the best known traditional Chinese medicines. Saponins are considered to be its active components. In this study, an HPLC method was first developed for the simultaneous quantitative analysis of thirteen saponins, including five triterpenoid saponins and eight steroidal saponins, in a series of YNBY preparations, i. e., powder, capsules, aerosol, toothpaste, plaster, and adhesive bandage. The pre‐treatment methods for each dosage form were investigated and optimized. The HPLC separation was performed on a Shim‐pack C₁₈ reversed‐phase column in gradient mode with UV detection at 203 nm. All calibration curves showed good linear regression (r² ? 0.9981) within the test ranges. Precisions and repeatabilities of the methods were better than 4.22 and 4.78%, respectively. Recoveries were better than 90.5%, even in the analysis of the least abundant saponins in a complex YNBY plaster. HPLC–ESI‐TOF/MS was used for definite identification of compounds in the preparations. This proposed method was successfully applied to quantify the 13 bioactive constituents in 27 commercial samples to evaluate the quality of YNBY preparations. The overall results demonstrate that this method is simple, reliable, and suitable for the quality control of YNBY. Furthermore, the retention behavior of these saponins in reversed‐phase chromatography is described.     

反相高效液相色谱法快速检测大豆素火腿中5种防腐剂

建立一种快速检测大豆素火腿中的苯甲酸、山梨酸、脱氢乙酸、羟苯甲酯、羟苯乙酯5种防腐剂含量的反相高效液相色谱法。大豆素火腿样品用水-甲醇(2∶1)超声振荡提取,提取液沉淀蛋白后,用0.45μm滤膜过滤,以Angilent Zorbax SB-C18色谱柱分离,梯度洗脱,用二极管阵列检测器检测。5种防腐剂得到良好的分离,质量浓度在0.1~5.0μg/mL范围内与色谱峰面积线性相关,相关系数(r2)均大于0.995,加标回收率为80.8%~115.2%,方法检出限为0.03~0.17μg/mL,定量限为0.10~0.54μg/mL,重复性相对标准偏差为1.35%~3.78%(n=6)。该方法样品处理简单,准确度高,重复性好,检出限低,适用于大豆素火腿中防腐剂含量的监测。     

超临界流体色谱法分析大豆磷脂

 采用以CO2 为流动相的超临界流体色谱方法 ,以含 0 0 5 % (体积分数 )三乙胺的乙醇作为改性剂 ,对具有重要生物功能的大豆磷脂组成进行分析 ,获得了大豆磷脂提取物中 6个重要组分的定性结果 ,并讨论了流动相组成、操作温度和压力对分离的影响。对其中有代表意义的磷脂酰胆碱 (PC)进行了外标法定量分析 ,在PC质量浓度为0 0 2 0 g/L～ 0 0 75 g/L时具有较好的线性关系 ,PC加样回收率为 96 7% (n =5 ) ,重现性好。此方法可用于实际样品的分析。     

Präparative Hochdruck-Säulenflüssigkeits-Chromatographie

Several aspects of the apparatus and column technology of modern preparative column liquid chromatography are described together with a review of the present state of the art. We can state: one can today so construct and fill preparative high-speed columns that the separation and isolation of individual components from mixtures in quantities sufficient for tentative identification (spectroscopic and CHN analysis c. 1 mg), structural elucidation, or mechanical, physical, electrical and last but not least, biological tests (ca. 100 mg) is possible. Additionally, by optimal use of “scale up” columns one can provide an additional tool, which may be used for research and development on the gram scale and may be described as a modern time- and money-saving technique. Unfortunately, up until now, only few systematic studies and applications which make full use of the preparative possibilities of modern column chromatography have been published. Only a few of the instrument manufacturers and accessory suppliers are active in this area. For this reason, compared to the rate of development in analytical aspects, the development of commercial preparative equipment is less well advanced. There remain, therefore, several questions open regarding apparatus and operation of such preparative columns, e.g. batch versus continuous operation, or maximum attainable diameter of columns.     

Comparison of high-performance liquid chromatography and capillary electrophoresis for the determination of some bee venom components

HPLC and capillary electrophoretic (CE) methods were compared for the determination of phospholipase A₂ and melittin in bee venom. Size-exclusion chromatography on a Tessek Separon HEMA-BIO 40 column requires the use of a denaturing eluent (0.2% trifluoroacetic acid in 20% acetonitrile) to overcome non-specific interactions of some components, e.g., melittin. Reversed-phase HPLC on a HEMA-BIO 1000 C₁₈ column with gradient elution using water-acetonitrile mobile phases containing trifluoroacetic acid and UV spectrophotometric detection at 215 nm permits the identification and determination of the main bee venom components and their preparative chromatography. CE analysis for bee venom components is optimum with electrolyte system of 150 mM phosphoric acid (pH 1.8) with UV spectrophotometric detection at 190 nm. In comparison with HPLC, the CE method is cheaper and faster (6 min vs. 45 min) and the separation is more efficient.     

Development of a gradient elution preparative high performance liquid chromatography method for the recovery of the antibiotic ertapenem from crystallization process streams

A gradient elution preparative chromatography method was developed for the recovery of the antibiotic ertapenem from crystallization mother-liquor streams. The preparative HPLC method that was developed on the lab-scale employs an analytical size column of conventional dimensions (25 cm x 0.46 cm) packed with Kromasil C8 stationary phase. Gradient elution was used with aqueous acetic acid and acetonitrile as mobile phases. A target of processing approximately 30 mg of ertapenem per half an hour at a flow rate of 1.5 mL/min with high yield and adequate rejection of all major impurities was achieved. This corresponds to a productivity of approximately 0.6 kg ertapenem as free acid per kilogram of stationary phase per day (kkd). The scalability of the method was demonstrated by using a 5 cm i.d. column configuration to generate 10 g of purified ertapenem. This work complements a previous study improving on the productivity and throughput of the method by employing gradient elution and the use of crystallization to remove some key impurities that are chromatographically difficult to resolve [A. Vailaya, P. Sajonz, O. Sudah, V. Capodanno, R. Helmy, F.D. Antia, J. Chromatogr. A 1079 (2005) 80].