高速逆流色谱法对当归中石油醚萃取部位化学成分的分离纯化

采用高速逆流色谱法对当归石油醚萃取部位中4个主要化学成分进行分离纯化。选择Arizona溶剂体系作为高速逆流色谱分离的溶剂系统,经过实验条件优化,确定最佳溶剂为:正己烷-乙酸乙酯-甲醇-水(体积比6∶0.6∶3∶1)。高速逆流色谱分离时,采用有机相(上相)为固定相,水相(下相)为流动相,正相洗脱,流速为2mL/min,转速为900r/min,检测波长为254nm。当归石油醚萃取部位中的4种化学成分获得较好分离,经高效液相色谱检测,其纯度分别为78.5%、93.2%、98.9%、88.7%。通过1HNMR、IR和质谱分析,鉴别出其中1种化合物为藁本内酯。     

土豆叶中茄尼醇的高速逆流色谱法分离纯化及质谱解析

采用超微回流提取方法提取土豆叶中的茄尼醇,用高速逆流色谱(HSCCC)对粗提物中的茄尼醇进行分离纯化。以正己烷-甲醇(体积比为10∶7)作为两相溶剂系统,以其下相为流动相,上相为固定相,经过一步HSCCC从60 mg茄尼醇粗提物中分离得到了5 mg 纯度为98.7%的茄尼醇;对分离得到的茄尼醇进行大气压化学电离质谱解析,研究了茄尼醇的大气压化学电离质谱的一级电离规律和二级质谱裂解规律。     

高良姜中二苯基庚烷类化合物的高速逆流色谱分离制备

应用高速逆流色谱法(HSCCC)分离纯化了高良姜中3种二苯基庚烷类化合物。以正己烷-乙酸乙酯-甲醇-水(2:3:1.75:1, v/v/v/v)为两相溶剂系统,下相为固定相,上相为流动相,在主机转速为858 r/min、流速1.5 mL/min的条件下,从122.20 mg高良姜石油醚萃取物中经一步HSCCC分离可制备得到5R-羟基-7-(4-羟基-3-甲氧基苯基)-1-苯基-3-庚酮(7.37 mg)、7-(4-羟基-3-甲氧基苯基)-1-苯基-4E-烯-3-庚酮(9.11 mg)和1,7-二苯基-4E-烯-3-庚酮(15.44 mg),经高效液相色谱分析,纯度均大于93%,各化合物的结构由质谱和核磁共振氢谱、碳谱鉴定确证。该方法简便、快速、高效,可用于高良姜中二苯基庚烷类化合物的快速分离制备。     

夏天无生物碱的高速逆流色谱分离纯化

采用pH-区带精制逆流色谱与常规高速逆流色谱相结合的方法快速分离纯化夏天无总生物碱.利用pH-区带精制逆流色谱对夏天无总生物碱进行分离,以正己烷-乙酸乙酯-甲醇-水(5∶ 5∶ 2∶ 8, V/V, 上相加5 mmol/L三乙胺,下相加5 mmol/L HCl)为溶剂系统,上样量3.0 g,分离得到1个混合物和3个高纯度的生物碱单体:原阿片碱(375 mg)、苏元胡碱甲(362 mg)和比枯枯灵(246 mg), 其纯度分别为97.5%,95.6%和97.1%.所得混合物850 mg经常规高速逆流色谱二次分离,以正己烷-乙酸乙酯-甲醇-水(1∶ 0.8∶1.1∶ 1, V/V)为溶剂系统,得到比枯枯灵(105 mg)和四氢巴马亭(470 mg)单体,纯度分别为99.1%和99.7%.从该药材分得苏元胡碱甲,两种制备分离模式相结合,提高了夏天无生物碱的分离效率.     

高效逆流色谱法制备苏木中的氧化巴西木素

氧化巴西木素是苏木的主要化学成分之一,具有广泛的药理活性且常作为染色剂应用于各行各业。采用传统柱色谱法进行分离,不仅会造成色谱柱材料的污染,也会造成活性成分的损失。故采用高效逆流色谱(HPCCC)对苏木中的活性化合物氧化巴西木素进行分离纯化。苏木乙醇提取物经乙酸乙酯萃取后直接进行高效逆流色谱分离。首先利用基于薄层色谱的常用溶剂体系估算法和摇瓶法结合高效逆流色谱分析模式进行溶剂体系筛选。结果表明,最佳溶剂体系为氯仿-甲醇-水(4∶3∶2, v/v/v)。高效逆流色谱以反相模式为洗脱模式,主机转速为1 600 r/min,流速为10 mL/min,分离温度为25℃,检测波长为285 nm,在氯仿-甲醇-水(4∶3∶2, v/v/v)溶剂体系下,从500 mg苏木乙酸乙酯萃取物中一次性分离制备得到15.2 mg纯度为95.6%的氧化巴西木素及一微量成分caesappanin C。采用高效逆流色谱分离制备氧化巴西木素,可避免苏木中的活性成分氧化巴西木素对色谱柱中的固体填充材料染色和难以洗脱等问题,并缩短分离纯化工作时间,提高工作效率。故可将高效逆流色谱应用到苏木中其他色素化合物或其他染料植物的...     

高速逆流色谱法快速分离制备枸杞中莨菪亭

建立了用高速逆流色谱(HSCCC)从枸杞中快速分离莨菪亭的方法。将枸杞的乙醇提取物经D-101大孔树脂初步纯化后直接进行高速逆流色谱分离,用薄层色谱-荧光法考察了莨菪亭在不同溶剂体系中的分配情况。结果表明,最佳的溶剂体系为氯仿-甲醇-水(10:7:3, v/v/v),取上相为固定相,下相为流动相,在主机转速为850 r/min、流速为1.5 mL/min、检测波长为365 nm的条件下,从200 mg样品中一次性分离制备可得到10.2 mg纯度达到98.3%的莨菪亭。制备所得的莨菪亭与对照品的高效液相色谱(HPLC)保留时间一致,且经核磁共振氢谱、碳谱鉴定结构;纯度经HPLC法测定。研究发现,氯仿-甲醇-水(10:7:3, v/v/v)体系可连续二次进样而样品的峰形未受明显的影响。实验结果表明用薄层色谱-荧光法可快速选定HSCCC溶剂体系,进而可快速、简便地制备高纯度的莨菪亭。     

高速逆流色谱技术分离纯化天然产物中黄酮类化合物的研究进展

高速逆流色谱(HSCCC)技术是一种连续高效的新型液-液分配色谱技术,在中药、生化、食品、天然产物化学、环境分析等领域有着广泛的应用.本文综述了部分利用高速逆流色谱技术分离纯化已知和未知黄酮类化合物的文献报道,并介绍了几种新近发展的高速逆流色谱以及其在分离纯化黄酮类化合物和其它化合物中的应用.     

硅胶柱色谱结合高速逆流色谱法分离纯化荷花中黄酮类化合物

采用硅胶柱色谱结合高速逆流色谱法分离纯化了荷花中3种黄酮类化合物。荷花粗提物先经过硅胶柱色谱初步分离,得到黄酮含量高的组分,再经过高速逆流色谱分离,以乙酸乙酯-乙醇-水-乙酸(4:1:5:0.025, v/v/v/v)为两相溶剂系统,上相为固定相,下相为流动相,在主机转速800 r/min、流速2.0 mL/min、检测波长254 nm条件下,从150 mg样品中一次性分离制备得到6.1 mg槲皮素-3-O-β-D-葡萄糖醛酸苷(I), 14.8 mg杨梅素-3-O-β-D-葡萄糖苷(II)和20.2 mg紫云英苷(III),经高效液相色谱检测其纯度分别为97.0%、95.4%、96.3%,并通过质谱和核磁共振氢谱、碳谱鉴定各化合物的结构。该方法简便、快速、节省溶剂,可以对荷花中的黄酮类化合物进行快速有效的分离纯化,具有较好的实用价值,为荷花资源的进一步开发应用提供了参考依据。     

高速逆流色谱法分离当归挥发油中有效成分藁本内酯及其气相色谱-质谱法的分析和鉴别北大核心CSCD

提出了应用高速逆流色谱从当归挥发油中分离有效成分藁本内酯,探索这一分离条件的关键是两相溶剂体系的选择。根据分离目标物的极性以及选择两相溶剂应满足的3个条件((1)分层时间不超过30s;(2)对样品不引起分解;(3)目标成分的分配系数在0.5～2.0之间),经薄层色谱法及高效液相色谱法预选,最终从几种溶剂体系中筛选得到两相溶剂体系为正己烷-乙酸乙酯-乙醇-水(1+1+1+1)体系。采用这一溶剂体系,一次进样500mg当归挥发油,可达到目标组分与其他杂质完全分离,目标组分回收后得到48mg藁本内酯。对此分离所得组分经气相色谱-质谱法(GC-MS)分析,其纯度达到98.5%以上,GC-MS还对此组分进行结构鉴定,证明其确为藁本内酯。     

高速逆流色谱与质谱联用在中药分析中的应用

高速逆流色谱 ( High- speed countercurrent chromatography,HSCCC)是新型的液 -液分配色谱技术 ,它利用多层螺旋管同步行星式离心运动 ,在短时间内实现样品在互不相溶的两相溶剂系统中的高效分配 ,从而实现样品分离[1] . HSCCC分离纯化后 ,若用 MS离线检测 ,此时须挥发原 HSCCC的溶剂体系 ,才能实现样品转移 ,还可能会带来样品污染 .HSCCC与 MS的联用克服了这些缺陷 ,具有很强的实用价值 .丹参酮 A( Tashinone A)是一种结晶性菲醌类化合物 [2 ] ,在丹参乙醚提取物中含量丰富 .本文采用正己烷 -乙醚 -乙醇 -水体系 ,将 HSCC…     

Application of preparative high-speed counter-current chromatography for separation and purification of arctiin from Fructus Arctii

Following an initial clean-up step on the AB-8 resin (polystyrene resin, 0.3-1.25 mm: NanKai Chemical Factory, Tianjin, China), high-speed counter-current chromatography (HSCCC) was used to purify an arctiin from an extract of the fruits of the Arctium lappa L. Arctiin is a major lignan compound in the traditional Chinese medicinal herb A. lappa L. The two-phase solvent system used was composed of ethyl acetate-n-butanol-ethanol-water at an optimized volume ratio of 5:0.5:1:5 (v/v/v/v). The upper phase was used as the mobile phase in the head to tail elution mode. A total amount of 159 mg of arctiin at 98% purity was obtained from 350 mg of the crude extract (containing 49% arctiin) with 91% recovery. The preparative isolation and purification of arctiin by HSCCC was completed in 5 h in a separation. Identification of the target compound was performed by LC-electrospray ionization MS and 13C-NMR. The structure of the product was further confirmed by comparison with authentic sample (National Institute of the Control of Pharmaceutical and Biological Products, Beijing, China).     

Preparative isolation and purification of bergapten and imperatorin from the medicinal plant Cnidium monnieri using high-speed counter-current chromatography by stepwise increasing the flow-rate of the mobile phase

A high-speed counter-current chromatography (HSCCC) method was developed for the preparative separation and purification of bergapten and imperatorin from the Chinese medicinal plant Cnidium monnieri (L.) Cusson. The crude extract was obtained by extraction with ethanol from the dried fruits of Cnidium monnieri (L.) Cusson under sonication. Preparative HSCCC with a two-phase solvent system composed of n-hexane-ethyl acetate-ethanol-water (5:5:5:5, v/v/v/v) was successfully performed by increasing the flow-rate of the mobile phase stepwise from 1.0 to 2.0 ml min(-1) after 180 min. The components purified and collected were analyzed by high-performance liquid chromatography. The method yielded 45.8 mg of bergapten at 96.5% purity and 118.3 mg of imperatorin at 98.2% purity from 500 mg of the crude extract in a single run. The recoveries of bergapten and imperatorin were 92.1 and 93.7%, respectively.     

高速逆流色谱法分离制备中药诃子中的没食子酸

利用高速逆流色谱法从100 mg诃子醇提物中一次性分离制备得到8.6 mg没食子酸。通过分析型高速逆流色谱对5种溶剂系统进行筛选,确定以正己烷-乙酸乙酯-甲醇-水(体积比为1:5:1:5)为两相溶剂体系并放大到制备型上,以上相为固定相,下相为流动相,在主机转速850 r/min、流动相流速2 mL/min、检测波长254 nm的条件下进行分离制备,获得4个分离峰(组分Ⅰ、Ⅱ、Ⅲ、Ⅳ)。经高效液相色谱检测,按照面积归一法计算,其中组分Ⅲ的纯度达96.40%。经电喷雾电离质谱分析,并结合与没食子酸标准品的高效液相色谱测定结果的对比,确定组分Ⅲ为没食子酸。该方法简便、快速、重复性好,适合于诃子中没食子酸的分离制备。     

Separation and purification of isoflavones from Pueraria lobata by high-speed counter-current chromatography.

High-speed counter-current chromatography (HSCCC) was applied to the semipreparative separation and purification of puerarin and related isoflavones from a crude extract of Pueraria lobata. Analytical HSCCC was used for the preliminary selection of a suitable solvent system composed of ethyl acetate-n-butanol-water (2:1:3, v/v/v). Using the above solvent system the preparative HSCCC was successfully performed yielding six relatively pure isoflavones including puerarin from 80 mg of the crude extract in one-step separation.     

Isolation and purification of acteoside and isoacteoside from Plantago psyllium L. by high-speed counter-current chromatography

Two isomeric phenylethanoid glycosides, acteoside and isoacteoside were isolated and purified from the seeds of Plantago psyllium L. for the first time by high-speed counter-current chromatography (HSCCC) using a solvent system consisting of ethyl acetate-water (1:1, v:v). By injecting 200 mg of the n-butanol extract of P. psyllium for five consecutive times, the two-step HSCCC procedure yielded a total of 165 mg of acteoside and 17.5 mg of isoacteoside from 978 mg extract. The recovery rates for acteoside and isoacteoside were 90 and 84%, respectively, and the purities were 98 and 94%, respectively. The HSCCC fractions were analyzed by HPLC and the structures were identified by UV, LC-APCI-MS in negative ion mode, and confirmed by NMR experiments.     

Preparative isolation and purification of two benzoxazinoid glucosides from Acanthus ilicifolius L. by high-speed counter-current chromatography

The first preparative separation of two benzoxazinoids, (2R)-2-O-beta-d-glucopyranosyl-2H-1,4-benzoxazin-3(4H)-one (HBOA-Glc) and (2R)-2-O-beta-d-glucopyranosyl-4-hydroxy-2H-1,4-benzoxazin-3(4H)-one (DIBOA-Glc), by means of high-speed counter-current chromatography (HSCCC) from the n-butanol extract of Acanthus ilicifolius L. is presented. The two-phase solvent system containing ethyl acetate-n-butanol-0.5%NH(4)OH (2:3:5, v/v/v, system B) was selected for the one-step HSCCC separation of HBOA-Glc and DIBOA-Glc according to the partition coefficient values (K) for target compounds and the separation factor (alpha) between the two target compounds. In the one-step HSCCC separation using solvent B, from 100mg n-butanol extract of A. ilicifolius, 6.3 mg HBOA-Glc and 6.8 mg DIBOA-Glc were isolated with purities of 90.3% and 80.2%, respectively. In order to obtain the two target compounds with higher purity, a second separation process was developed comprising two steps. In the two-step separation, the sample was first pre-purified by HSCCC using ethyl acetate-n-butanol-water (2:3:5, v/v/v, system A) solvent system and then purified using solvent system B. A 100-mg amount of the n-butanol extracts of A. ilicifolius was separated to yield 5.8 mg of HBOA-Glc and 4.8 mg of DIBOA-Glc with purities of 97.1% and 94.8%, respectively, which were directly used for NMR analyses.     

Preparative isolation and purification of lutein from the microalga chlorella vulgaris by high-speed counter-current chromatography

High-speed counter-current chromatography (HSCCC) was applied to the isolation and purification of lutein from microalgae. Analytical HSCCC was used for the preliminary selection of a suitable solvent system composed of n-hexane-ethanol-water (4:3:1, v/v). Using the above solvent system, preparative HSCCC was successfully performed yielding lutein at 98% purity from 200 mg of the crude extract in a one-step separation.     

高速逆流色谱分离纯化蔓荆子中的活性成分

应用高速逆流色谱法(HSCCC)分离纯化蔓荆子中的活性成分。以石油醚-乙酸乙酯-甲醇-水(体积比为3:6:3.6:3)为两相溶剂体系,在转速为800 r/min、流速为1.5 mL/min、检测波长为254 nm的条件下进行分离,所得馏分经高效液相色谱法(HPLC)检测,并经电喷雾电离(ESI)质谱和核磁共振谱(NMR)鉴定化合物的结构。从250 mg蔓荆子粗提物中一次性分离得到4个化合物,分别为23 mg对羟基苯甲酸、15 mg 3,6,7-三甲基槲皮万寿菊素、24 mg蔓荆子黄素和5 mg蒿黄素,其纯度约为93.1%、 97.3%、 98.7%和98.5%。该法具有简便、快速、重复性好的优点,为分离蔓荆子中的活性成分提供了新的方法。