半制备型高速逆流色谱分离制备铁棒锤根中的一种咪唑生物碱

采用高速逆流色谱（HSCCC）技术从铁棒锤根氯仿提取物中分离制备了一种高纯度咪唑类生物碱1H-imidazole-2-carboxylic acid,butyl ester （ICABE）。采用高效液相色谱（HPLC）测定目标化合物在两相溶剂中的分配系数,优化HSCCC分离ICABE的溶剂体系,确定了以正己烷-氯仿-乙醇-水（10：1：13：2,v/v/v/v）为HSCCC的两相溶剂系统,以上相为固定相,下相为流动相,流动相流速为1.8 mL/min,主机转速850 r/min,检测波长为230 nm条件下进行分离制备,在350 min内从100 mg粗样品中一步分离得到7.5 mg ICABE,经HPLC检测其纯度达98%以上（峰面积归一化法）,结构由UV、¹H-NMR和¹³C-NMR得以鉴定。该方法简便、快速,所得产物纯度高,适合于铁棒锤中ICABE的制备分离。     

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。     

高速逆流色谱分离制备椭圆叶花锚中的2种口山酮苷元

椭圆叶花锚的主要活性成分为口山酮类化合物,这类化合物具有利胆、抗炎、抗菌及抗病毒活性。应用高速逆流色谱法建立了2种高纯度口山酮苷元的分离制备方法。对椭圆叶花锚氯仿萃取部位运用高速逆流色谱分离纯化,以正己烷-乙酸乙酯-甲醇-水(5:5:7:5, 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,流动相流速1.5 mL/min,检测波长254 nm条件下进行分离制备。所得产物经高效液相色谱分析检测,其化学结构由核磁共振氢谱(1H NMR)和核磁共振碳谱(13C NMR)鉴定。在此条件下,从100 mg粗样品中一步分离得到18 mg 1-羟基-2,3,5-三甲氧基口山酮,14 mg 1-羟基-2,3,4,5-四甲氧基口山酮。经高效液相色谱分析,其纯度均达98%以上。该方法简便、快速,所得产物纯度高,适合于椭圆叶花锚口山酮苷元的制备分离。     

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。     

玛咖样品中9种玛咖酰胺含量的高效液相色谱法测定及质谱确证

为建立玛咖(Lepidiummeyenii Walp.)中活性成分9种玛咖酰胺(3-甲氧基苄基亚麻酰胺、苄基亚麻酰胺、3-甲氧基苄基亚油酰胺、苄基亚油酰胺、3-甲氧基十六烷酰胺、苄基十六烷酰胺、苄基油酰胺、苄基十七烷酰胺和苄基十八烷酰胺)的高效液相色谱方法,用ODS-3色谱柱(C_(18),5μm,4.6×250 mm),乙腈-水(0.2%甲酸)(V/V=90/10)为流动相,等梯度洗脱,柱温30℃,流速1.0 m L/min,采用紫外检测器(UV)检测,检测波长210 nm。方法学考察表明,在一定范围内线性良好(R~20.999),9种玛咖酰胺回收率高于88.3%,日内日间精密度,最低检测限和定量限的范围均符合标准,对样品进行液质联用确认。该方法适用于玛咖制品中9种玛咖酰胺的的质量控制。     

生附子中C19型二萜生物碱的高速逆流色谱分离及其结构鉴定

应用高速逆流色谱法分离制备了生附子中的3个C19型二萜生物碱类化合物。以正己烷-乙酸乙酯-甲醇-水(3:5:4:5, 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850 r/min、流动相流速2.0 mL/min、检测波长235 nm条件下进行分离制备;一次性从90 mg附子总碱粗提物中分离制备得到15.3 mg北草乌碱,35.1 mg中乌头碱和22.7 mg次乌头碱,经高效液相色谱分析,测得它们的纯度分别为97.9%、96.2%和99.2%。并应用波谱(电喷雾离子质谱、核磁共振氢谱和核磁共振13C谱)解析法确定了它们的结构。利用该方法可以对生附子中的二萜类生物碱成分进行快速的分离和纯化     

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。     

高速逆流色谱法分离制备母丁香和公丁香中的5种非挥发性化合物

应用高速逆流色谱法从母丁香和公丁香中快速分离了3种已知非挥发性化合物,并利用相同方法从公丁香中分离出2种色原酮类化合物。两相溶剂系统A为正己烷-乙酸乙酯-甲醇-水(5:8:6:13, v/v/v/v),系统B为正己烷-乙酸乙酯-甲醇-水(5:8:9:10, v/v/v/v),以系统A的上相为固定相,系统A和B的下相为流动相,利用梯度洗脱方式,在主机转速为880 r/min、流速1.2 mL/min条件下,成功地从70 mg母丁香粗提物中分离得到12.3 mg鞣花酸、9.6 mg鼠李素、17.2 mg槲皮素,从50 mg公丁香粗提物中分离得到5,7-二甲氧基-2-甲基色原酮10.2 mg、5,7-二甲氧基-2,6-二甲基色原酮8.6 mg,纯度均在96%以上。各化合物的结构均由质谱和核磁共振氢谱、碳谱鉴定。利用该方法可以对丁香不同药用部位中的非挥发性化合物进行有效的分离和纯化。     

漆酚酯键合硅胶液相色谱固定相的制备与应用

以甲基丙烯酸漆酚酯为色谱配体,制备了一种新型色谱固定相。首先以漆酚和甲基丙烯酰氯为原料制备得到甲基丙烯酸漆酚酯,并通过物理吸附涂覆到由3-（甲基丙烯酰氧）丙基三甲氧基硅烷化学修饰的硅胶上,再通过自由基引发与硅烷化硅胶的双键聚合制得漆酚酯键合硅胶固定相（USP）。对固定相进行傅里叶红外光谱（FT-IR）、热重分析（TGA）、扫描电子显微镜（SEM）和元素分析（EA）表征,结果表明通过共聚反应成功地将漆酚酯固定在硅烷化硅胶上,且制备出的固定相具有良好的单分散性。采用匀浆法装柱,以乙腈-0.05%磷酸溶液（3：97,v/v）为流动相,流速为0.4 mL/min,检测波长为220 nm,考察固定相对天麻浸膏的分离性能。以乙腈-水（50：50,v/v）为流动相,流速为0.5 mL/min,检测波长为290 nm,考察固定相对吴茱萸浸膏的分离性能。结果表明该固定相对天麻浸膏和吴茱萸浸膏均具有良好的分离性能,从天麻浸膏中分离出5个色谱峰,从吴茱萸浸膏中分离出2个色谱峰。与商品化C₁₈ 柱相比,USP柱可以从天麻浸膏中分离出更多的有效组分并实现基线分离,分离吴茱萸浸膏的色谱条件更为环保和安全。采用低流速对天麻浸膏和吴茱萸浸膏进行分离,减少了流动相的使用量,分离结果令人满意。以天然产物漆酚制备色谱固定相,既为分离纯化天麻素和吴茱萸碱提供了一种新的方法,又为液相色谱固定相制备提供了新的思路,还拓展了生漆在色谱分离材料方面的应用。     

高速逆流色谱分离纯化九里香中的黄酮类化合物

应用高速逆流色谱法分离纯化了九里香中的4种黄酮类化合物。以石油醚-乙酸乙酯-甲醇-水(5:5:4.8:5, v/v/v/v)作为两相溶剂系统,上相为固定相,下相为流动相,以主机转速800 r/min、流速2.0 mL/min、单次进样量200 mg的条件成功地从4.0 g九里香粗提物中分离纯化出54.31 mg 5,7,3′,4′,5′-五甲氧基黄酮(重结晶后)、107.68 mg 5-羟基-6,7,3′,4′-四甲氧基黄酮、215.54 mg 5-羟基-6,7,8,3′,4′-五甲氧基黄酮、84.36 mg 5-羟基-6,7,8,3′,4′,5′-六甲氧基黄酮,纯度均在95%以上。各化合物的结构均由质谱和核磁共振氢谱、碳谱鉴定。其中化合物5-羟基-6,7,3′,4′-四甲氧基黄酮为首次从九里香中分离得到。     

Preparative separation and purification of squalene from the microalga Thraustochytrium ATCC 26185 by high-speed counter-current chromatography

High-speed counter-current chromatography (HSCCC) was successfully applied to the preparative separation and purification of squalene from microalgae. Crude squalene was obtained from the microalga Thraustochytrium ATCC 26185 by extraction with organic solvents. The crude squalene was further separated using a waterless two-phase solvent system composed of n-hexane-methanol (2:1, v/v). The upper phase as the mobile phase was pumped into the column at a flow-rate of 2.0 ml min(-1) in the tail-to-head elution mode. The fractions purified and collected were analyzed by high-performance liquid chromatography. The method yielded 0.2 mg squalene at 96% purity from 150 mg of the crude squalene (0.14% squalene) with 95% recovery. The separation of squalene by HSCCC was completed in 90 min.     

Separation of α-cyclohexylmandelic acid enantiomers using biphasic chiral recognition high-speed counter-current chromatography

This work concentrates on a chiral separation technology named biphasic recognition applied to resolution of α-cyclohexylmandelic acid enantiomers by high-speed counter-current chromatography (HSCCC). The biphasic chiral recognition HSCCC was performed by adding lipophilic (−)-2-ethylhexyl tartrate in the organic stationary phase and hydrophilic hydroxypropyl-β-cyclodextrin in the aqueous mobile phase, which preferentially recognized the (−)-enantiomer and (+)-enantiomer, respectively. The two-phase solvent system composed of n-hexane-methyl tert-butyl ether–water (9:1:10, v/v/v) with the above chiral selectors was selected according to the partition coefficient and separation factor of the target enantiomers. Important parameters involved in the chiral separation were investigated, namely the types of the chiral selectors (CS); the concentration of each chiral selector; pH of the mobile phase and the separation temperature. The mechanism involved in this biphasic recognition chiral separation by HSCCC was discussed. Langmuirian isotherm was employed to estimate the loading limits for a given value of chiral selectors. Under optimum separation conditions, 3.5–22.0 mg of α-cyclohexylmandelic acid racemate were separated using the analytical apparatus and 440 mg of racemate was separated using the preparative one. The purities of both of the fractions including (+)-enantiomer and (−)-enantiomer from the preparative CCC separation were over 99.5% determined by HPLC and enantiomeric excess reached 100% for the (±)-enantiomers. Recovery for the target compounds from the CCC fractions reached 85–88% yielding 186 mg of (+)-enantiomer and 190 mg of (−)-enantiomer. The overall experimental results show that the HSCCC separation of enantiomer based on biphasic recognition, in which only if the CSs involved will show affinity for opposite enantiomers of the analyte, is much more efficient than the traditional monophasic recognition chiral separation, since it utilizes the cooperation of both of lipophilic and hydrophilic chiral selectors.     

Separation of phenylsuccinic acid enantiomers using biphasic chiral recognition high‐speed countercurrent chromatography

High‐speed countercurrent chromatography (HSCCC) combined with biphasic chiral recognition was successfully applied to the resolution of phenylsuccinic acid enantiomers. d ‐Isobutyl tartrate and hydroxypropyl‐β‐cyclodextrin were employed as lipophilic and hydrophilic selectors dissolved in the organic stationary phase and aqueous mobile phase, respectively. The two‐phase solvent system was made up of n‐hexane/methyl tert‐butyl ether/water (0.5:1.5:2, v/v/v). Impacts of the type and concentration of chiral selectors, the pH value of the aqueous phase solution as well as the temperature on the separation efficiency were investigated. By means of preparative HSCCC, pure enantiomer was obtained by separating 810 mg of racemate with a purity >99.5% and a recovery rate between 82 and 85%. The experimental results indicate that biphasic recognition HSCCC provide a promising means for efficient separation of racemates.     

高速逆流法对刺五加有效成分刺五加苷E的分离制备

 采用高速逆流法分离纯化刺五加粗品中的刺五加苷E。溶剂系统为氯仿 甲醇 异丙醇 水,体积比为5∶6∶1∶4,上相为固定相,下相为流动相,转速为800r/min,流速为2 0mL/min。所得刺五加苷E经高效液相分析,测定纯度为98%(峰面积百分比)。这为其他苷类等极性物质的分离纯化提供了依据。     

Isolation and purification of baicalein, wogonin and oroxylin A from the medicinal plant Scutellaria baicalensis by high-speed counter-current chromatography

The medicinal plant Scutellaria baicalensis Georgi has been used widely in traditional Chinese medicine for anti-inflammation, anticancer, antiviral and antibacterial infections, reducing the total cholesterol level and decreasing blood pressures. A high-speed counter-current chromatography (HSCCC) method was developed for the preparative separation and purification of three bioactive flavonoids, namely, baicalein, wogonin and oroxylin A, from S. baicalensis Georgi. Preparative HSCCC with a two-phase solvent system composed of n-hexane-ethyl acetate-n-butanol-water (1:1:8:10, 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 4 h. The components purified and collected were analyzed by high-performance liquid chromatography. The method yielded 144.8 mg of baicalein at 95.7% purity, 50.2 mg of wogonin at 98.5% purity, and 12.4 mg of oroxylin A at 93.2% purity from 500 mg of the crude extract in a one-step separation. The recoveries of baicalein, wogonin and oroxylin A were 92.7%, 91.6% and 92.5%, respectively.     

Isolation and purification of inflacoumarin A and licochalcone A from licorice by high-speed counter-current chromatography

High-speed counter-current chromatography (HSCCC) technique in semi-preparative scale has been applied to isolate and purify bioactive flavone compounds from the ethanol extract of Glycyrrhiza inflata Bat., a particular plant species of licorice. HSCCC separation was performed with a two-phase solvent system composed of n-hexane-chloroform-methanol-water (5:6:3:2, v/v) by eluting the lower mobile phase at a flow rate of 1.8 ml/min and a revolution speed of 800 rpm. Purification was performed with a two-phase solvent system composed of n-hexane-chloroform-methanol-water (1.5:6:3:2, v/v) by eluting the lower mobile phase at a flow-rate of 1.5 ml/min and a revolution speed of 800 rpm. Two major flavone peaks: inflacoumarin A and licochalcone A were collected and the respective yields of the peaks amount to 6 mg (8.6%, w/w) and 8 mg (11.4%, w/w) from 70 mg of the crude extract sample. The purities of inflacoumarin A and licochalcone A reached 99.6% and 99.1%, respectively, after a sequential purification run. The structures of inflacoumarin A and licochalcone A were positively confirmed by 1H NMR and 13C NMR, 1H-13C-COSY, UV, FT-IR and electron ionization MS analyses.