Wang Yarong, Chen Yang, Deng Liang, Cai Shining, Liu Jia, Li Wenna, Du Lianfeng, Cui Guozhen, Xu Xin, Lu Tao, Chen Ping, Zhang Hao
Department of Pharmaceutical Sciences, Zunyi Medical University, Zhuhai Campus, Zhuhai, Guangdong, 519041, PR China.
Phytochem Anal. 2015 May-Jun;26(3):202-8. doi: 10.1002/pca.2553. Epub 2015 Jan 27.
Iridoid glycosides and crocetin derivatives are the main bioactive components of Gardenia. The processes of separation of these compounds reported in much of the literature are tedious, time consuming and require multiple chromatographic steps, which results in lower recovery and higher costs.
To develop a high-speed counter-current chromatography (HSCCC) method for the systematic separation and purification of iridoid glycosides and crocetin derivatives on a preparative scale from Gardenia.
After fractionation using HPD100 column chromatography, n-butanol:ethanol:water (10:1:10, v/v) was selected to purify gardenoside, 6β-hydroxy geniposide and geniposidic acid from fraction A; ethyl acetate:n-butanol:water (2:1.5:3, v/v) was used to isolate geniposide from fraction B; crocin-1, crocin-2, crocin-3 and crocin-4 were purified by hexane:ethyl acetate:n-butanol:water (1:2:1:5, v/v) from fraction C. The head-to-tail elution mode was used with a flow rate of 8.0 mL/min and a rotary speed of 600 rpm.
After HSCCC isolation, 151.1 mg of gardenoside, 52.2 mg of 6β-hydroxy geniposide and 24.5 mg of geniposidic acid were obtained from 800 mg of fraction A; 587.2 mg of geniposide was obtained from 800 mg of Fraction B; 246.2 mg of crocin-1, 34.2 mg of crocin-2, 24.4 mg of crocin-3 and 24.7 mg of crocin-4 were obtained from 1000mg of fraction C. Their purities were found by UPLC analysis to be 91.7%, 93.4%, 92.5%, 98.2%, 94.1%, 96.3%, 94.1% and 98.9% respectively.
The present results demonstrates that the main iridoid glycosides and crocetin derivatives in Gardenia can be obtained efficiently from extracts using HSCCC.
环烯醚萜苷和西红花酸衍生物是栀子的主要生物活性成分。许多文献报道的这些化合物的分离过程繁琐、耗时,需要多个色谱步骤,这导致回收率较低且成本较高。
建立一种高速逆流色谱(HSCCC)方法,用于从栀子中制备规模系统分离和纯化环烯醚萜苷和西红花酸衍生物。
采用HPD100柱色谱进行分馏后,选择正丁醇:乙醇:水(10:1:10,v/v)从馏分A中纯化栀子苷、6β-羟基栀子苷和栀子苷酸;用乙酸乙酯:正丁醇:水(2:1.5:3,v/v)从馏分B中分离栀子苷;用正己烷:乙酸乙酯:正丁醇:水(1:2:1:5,v/v)从馏分C中纯化西红花苷-1、西红花苷-2、西红花苷-3和西红花苷-4。采用头对尾洗脱模式,流速为8.0 mL/min,转速为600 rpm。
经HSCCC分离后,从800 mg馏分A中获得151.1 mg栀子苷、52.2 mg 6β-羟基栀子苷和24.5 mg栀子苷酸;从800 mg馏分B中获得587.2 mg栀子苷;从1000 mg馏分C中获得246.2 mg西红花苷-1、�4.2 mg西红花苷-2、24.4 mg西红花苷-3和24.7 mg西红花苷-4。通过超高效液相色谱分析发现它们的纯度分别为91.7%、93.4%、92.5%、98.2%、94.1%、96.3%、94.1%和98.9%。
目前的结果表明,使用HSCCC可以从提取物中高效获得栀子中的主要环烯醚萜苷和西红花酸衍生物。
