大孔吸附树脂纯化迷迭香脂溶性总酚酸的研究

从X-5、D4020、AB-8、H1020、NKA-Ⅱ、HPD-100A、SIPI、HPD800和D3520大孔吸附树脂中筛选出H1020树脂,研究了其对迷迭香脂溶性总酚酸的静态与动态吸附和解吸性能.结果表明,H1020树脂对迷迭香脂溶性总酚酸的饱和吸附量为19.84mg/g干树脂,饱和吸附时间为3h,适宜的解吸荆为体积分数90%的乙醇溶液;以质量浓度为4.45m/mL的迷迭香提取液上柱,流速为1.0mL/min,当吸附平衡后,2.7BV体积分数90%的乙醇溶液可将吸附的总酚酸完全洗脱.经动态纯化后,脂溶性总酚酸质量分数从47.74%提高到70.46%,该组分清除DPPH自由基的IC50值为0.0469mg/mL.     

大孔吸附树脂分离纯化枣渣中三萜酸的研究

研究枣渣中三萜酸的分离纯化工艺条件,为枣渣二次开发利用提供依据.筛选合适的大孔树脂,并对大孔树脂分离纯化的条件进行考察.初步确定了树脂分离纯化的条件,上样浓度为3.5mg/mL,洗脱剂为pH值为10的90%乙醇溶液,回收率65%以上,纯度达80%以上.此工艺安全,环保,提取物纯度较高,适用于工业化生产.对X-5树脂吸附总三萜酸的动力学研究表明吸附速率同时受液膜扩散和颗粒扩散控制.     

大孔吸附树脂对莲房原花青素吸附纯化性能的研究

比较了14种大孔吸附树脂对莲房中原花青素(proanthocyanidins of lotus seedpod,LSPAs)的吸附及解吸性能,在研究静态吸附的基础上,筛选出效果较好的树脂进行动态实验研究,并对所得组分LSPAs含量及其相对分子量进行初步分析.结果表明,DM130大孔吸附树脂分离纯化LSPAs效果最佳,上样浓度为2.5mg/mL,流速为3BV/h时,饱和吸附量为4～4.5个BV;当用体积分数为50%乙醇以3BV/h的流速洗脱5BV时,LSPAs的累积回收率可达96.43%,含量从22.54%提高到95.31%;经质谱分析,(M+H)分子量范围为291.1～1155.3,聚合度≤4.     

几种吸附树脂对五氯酚钠吸附性能的研究

研究了几种树脂对五氯酚钠的吸附能力,其中戊二醛交联的壳聚糖树脂不仅有较好的吸附效果,动态吸附容量为187.5mg/g干树脂,而且易洗脱,洗脱率高达90%以上。     

XAD-16树脂分离纯化怀菊花黄酮的工艺研究

研究XAD-16树脂分离纯化怀菊花黄酮的工艺,探讨了吸附过程中树脂的等温吸附与吸附动力学,并应用Langmuir方程与Freundlich方程对吸附过程进行了拟合。确定了XAD-16树脂分离怀菊花黄酮的最佳工艺条件:上样浓度2.0mg/mL,上样流速1BV/h,冲洗杂质用水量11BV,洗脱剂为85%(体积分数)乙醇,洗脱流速2BV/h,洗脱剂体积5BV。此时总黄酮的解吸率为83.9%。在此条件下,经过XAD-16树脂分离纯化后,怀菊花总黄酮含量达到77.2%。     

大孔吸附树脂对熊果酸吸附性能的研究

研究了从山楂叶中纯化熊果酸的柱层析工艺。静态吸附结果表明,X-5、NKA和AB-8树脂的吸附率分别为91.32%,72.28%和41.19%;以90%乙醇为洗脱剂,X-5、NKA和AB-8树脂的洗脱率分别为83%,70%,87%。静态实验表明X-5树脂具有较好的吸附解吸性能。动态实验优化了在X-5树脂中的流速、上样液的熊果酸浓度和上样体积。结果表明,流速为3BV/h(BV为倍量体积),上样液的熊果酸浓度为0.304mg/mL,上样体积为3BV为最优上样条件。动态洗脱中采用梯度洗脱方式,结果表明在90%的乙醇洗脱下,熊果酸纯度达93.21%。对层析工艺制备的熊果酸进行结晶处理,所获得的熊果酸纯度为98.61%,与熊果酸标准品的红外光谱一致。     

大孔吸附树脂分离提取多杀菌素

采用大孔吸附树脂法分离提取多杀菌素.从11种大孔吸附树脂中筛选出DM11进行了静态、动态吸附性能实验,并考察了不同吸附、解吸条件的影响.结果表明,DM11的静态吸附容量为25.63mg/g(wet resin),其吸附等温线符合Langmuir吸附等温式.采用丙酮做洗脱剂,洗脱率为97.5%,动态吸附最佳吸附pH为9.5,吸附流速为6BV/h,穿透吸附容量为21.2mg/ml(wet resin),洗脱流速1.5BV/h.     

火棘果总黄酮的提取和纯化研究

采用溶剂提取法、索氏提取法、循环超声提取法提取火棘果总黄酮,利用静态吸附方法筛选分离火棘果总黄酮的最适大孔树脂,利用动态吸附方法研究最适大孔树脂纯化火棘果总黄酮的条件,并用紫外分光光度法测定其含量。得出结果为循环超声提取时间短、效率高;D101大孔吸附树脂纯化效果最好,最佳工艺为上样浓度为0.899 8g·L-1,上样液pH为4,上样体积5BV,上样速率2.5mL·min-1,用5BV70%乙醇以2.0 mL·min-1速率洗脱,经树脂纯化后总黄酮的纯度由原来的9.00%提高至28.11%。     

大孔树脂-高速逆流色谱法分离纯化地黄中毛蕊花糖苷

该文建立了大孔树脂-高速逆流色谱分离中药材地黄中有效成分毛蕊花糖苷的方法。考察了4种大孔树脂对地黄粗提物中毛蕊花糖苷的静态吸附与解吸情况,其中D101大孔树脂对目标成分的吸附率与解吸率最理想,实验结果表明体积分数为10%的乙醇洗脱得到的毛蕊花糖苷含量最高,目标成分含量从4.9%提高到32.6%。最后,部分纯化的样品（165 mg）采用高速逆流色谱进一步纯化,两相溶剂系统由乙酸乙酯-正丁醇-水（1：4：5,v/v/v）组成,分离得到45 mg纯度为96%的毛蕊花糖苷。     

树脂法分离纯化倒提壶生物碱的研究

采用阳离子交换树脂和大孔吸附树脂联用的方法,将倒提壶生物碱提取液依次经过阳离子交换树脂和两次大孔吸附树脂,对其中的天芥菜碱和毛果天芥菜碱进行分离纯化。结果表明,倒提壶生物碱溶液采用阳离子交换树脂经过水洗和NaCl洗脱与大孔吸附树脂两次经乙醚和50%乙醇洗脱后,毛果天芥菜碱与天芥菜碱的纯度分别从0.73%和2.2%提高至81.6%和79.2%,提取量分别由4.6 mg/g和10.7 mg/g提高至50.6mg/g和92.7 mg/g。该文所建立的分离纯化方法具有成本低、污染小、周期短、操作简便和分离纯化效率高等特点,适合工业化生产。     

Enrichment of total steroidal saponins from the extracts of Trillium tschonoskii Maxim by macroporous resin and the simultaneous determination of eight steroidal saponins in the final product by HPLC

An effective and simple method was established for the separation and enrichment of steroidal saponins from Trillium tschonoskii Maxim. The adsorption and desorption properties of seven macroporous resins were investigated. Among the tested resins, AB‐8 resin showed the best adsorption and desorption capacities. The adsorption of steroidal saponins on AB‐8 at 25°C was quite consistent with both the Freundlich isotherm model and the pseudo‐second‐order kinetics model. By optimizing the dynamic adsorption and desorption parameters, the content of steroidal saponins increased from 5.20% in the crude extracts to 51.93% in the final product, with a recovery yield of 86.67%. Furthermore, by scale‐up separation, the concentration and recovery of total steroidal saponins were 43.8 and 85.5%, respectively, which suggested that AB‐8 resin had great industrial and pharmaceutical potential because of its high efficiency and cost‐effectiveness. In addition, a high‐performance liquid chromatography method for the simultaneous determination of eight steroidal saponins was established for the first time, which was employed to qualitatively and quantitatively analyze the final product. Based on the methodological validation results, the high‐performance liquid chromatography method can be widely applied to the quality control of steroidal saponins from Trillium tschonoskii Maxim due to its excellent accuracy, stability, and repeatability.     

Enrichment and purification of madecassoside and asiaticoside from Centella asiatica extracts with macroporous resins

In present study, the performance and separation characteristics of five macroporous resins for the enrichment and purification of asiaticoside and madecassoside from Centella asiatica extracts have been evaluated. The adsorption and desorption properties of total triterpene saponins (80% purity) on macroporous resins including HPD100, HPD300, X-5, AB-8 and D101 have been compared. According to our results, HPD100 offered higher adsorption and desorption capacities and higher adsorption speed for asiaticoside and madecassoside than other resins. Column packed with HPD100 resin was used to perform dynamic adsorption and desorption tests to optimize the separation process of asiaticoside and madecassoside from C. asiatica extracts. After the treatment with gradient elution on HPD100 resin, the content of madecassoside in the product increased from 3.9 to 39.7%, and the recovery yield was 70.4%; for asiaticoside the content increased from 2.0 to 21.5%, and the recovery yield was 72.0%. The results showed that HPD100 resin revealed a good ability to separate madecassoside and asiaticoside, and the method can be referenced for the separation of other triterpene saponins from herbal raw materials.     

Study on Adsorption and Separation of Naringin with Macroporous Resin

X-5 resin, with higher adsorption and easier desorption of naringin, was selected from five kinds of macroporous resins through static adsorption and desorption experiments. Effects of concentration, pH value, and flow rate of naringin extract on the adsorption of naringin by X-5 resin were studied. Meanwhile, the effect of these factors on the desorption of naringin from X-5 resin was also investigated. The experimental results show that the adsorption isotherm of naringin by X-5 resin can be described by the Langmuir isotherm equation. The static maximum adsorption capacity of naringin is 32.6 mg/g with naringin concentration at 2.7 g/L, while the dynamic adsorption capacity of naringin is 23.8 mg/g with naringin extract flow rate at two times that of resin volume per hour. The optimal eluant is 60% (v/v) ethanol-water with pH value of 10. The desorption ratio will rise to more than 85% when the flow rate of this optimal eluant is one to two times that of resin volume per hour. Translated from Journal of Central South University (Science and Technology)     

阿尔泰狗哇花总皂苷的提取与纯化

对阿尔泰狗哇花总皂苷的提取与纯化工艺进行了研究.利用正交设计确定了提取温度、乙醇浓度、溶剂用量、时间及次数等提取工艺参数.比较了五种大孔吸附树脂和聚酰胺树脂对阿尔泰狗哇花总皂苷的吸附与脱附性能.结果表明,在优化的提取条件下提取,经AB-8大孔吸附树脂柱层析分离纯化,制得总皂苷产品,其含量比原药材提高约7倍多,进一步完善后可适用于工业化生产.     

Optimization of luteolin separation from pigeonpea [Cajanus cajan (L.) Millsp.] leaves by macroporous resins

In the present study, the performance and separation characteristics of eight macroporous resins for the separation of luteolin (LU) from pigeonpea leaves extracts have been evaluated. The adsorption and desorption properties of LU on macroporous resins including AB-8, NKA-9, NKA-2, D3520, D101, H1020, H103 and AL-2 have been compared. AL-2 resin offers the best adsorption and desorption capacity for LU than other resins based on the research results, and its adsorption data at 25 degrees C fit best to the Freundlich isotherm. Dynamic adsorption and desorption experiments have been carried out with the column packed by AL-2 resin to optimize the separation process of LU from pigeonpea leaves extracts. The optimum parameters for adsorption were sample solution LU concentration 65.5 microg/ml, pH 5, processing volume 3 BV, flow rate 1.5BV/h, temperature 25 degrees C; for desorption were elution solvent ethanol-water (50:50, v/v) 2 BV and followed by ethanol-water (60:40, v/v) 2 BV, and flow rate 1BV/h. After treated with AL-2 resin, the LU content in the product was increased 19.8-fold from 0.129% to 2.55%, with a recovery yield of 78.54%. The results showed that AL-2 resin revealed a good ability to separate LU. Therefore, we conclude that results in this study may provide scientific references for the large-scale LU production from pigeonpea or other plants extracts.     

Separation and purification of flavonoid from Taxus remainder extracts free of taxoids using polystyrene and polyamide resin

An efficient separation process of flavonoid from Taxus wallichiana var. mairei remainder extracts free of taxoids was developed in this study. AB‐8 macroporous resin and polyamide resin offered the fine adsorption capacity, and its adsorption rate at 30°C fitted well to the Langmuir and Freundich isotherms. Resin dynamic adsorption and desorption experiments were conducted to optimize the separation process of total flavonoids from T. wallichiana var. mairei remainder extracts free of taxoids. The optimum parameters for adsorption by AB‐8 resin were as follows: (1) the concentration of flavonoids in a sample solution of 5.61 mg/mL with a processing volume of 2 bed volume (BV) (60 mL); (2) for desorption, ethanol–water (80:20, v/v), with 6 BV as an eluent at a flow rate of 2 BV/h. After a one‐run treatment with AB‐8 resin, the content of flavonoids was increased 5.10‐fold from 4.05 to 20.65%. The optimum parameters for adsorption by polyamide resin were as follows: processing volume of 2 BV (30 mL); for desorption, ethanol–water (70:30, v/v), with 8 BV as an eluent at a flow rate of 2 BV/h. After one‐run treatment with polyamide resin, the content of total flavonoids increased from 20.65 to 65.21%. The method will provide a potential approach for large‐scale separation and purification of flavonoid for its wide pharmaceutical use.     

大孔树脂分离纯化丹酚酸的研究

比较了D301R、D392、D380大孔阴离子交换树脂和X-5.AB-8、NKA-9、SP825大孔吸附树脂对丹参水溶性成分的吸附和解吸能力,筛选出效果较好的SP825进行分离纯化丹酚酸的研究.实验表明,大孔吸附树脂SP825能分离出纯度为95.32%的丹参素,在梯度洗脱条件下可得到以丹参素(水洗脱)和丹酚酸B(乙醇洗脱)为主的产品.在最佳吸附与解吸工艺参数下,丹参素、紫草酸、迷迭香酸、丹酚酸A和丹酚酸B的收率分别为:36.92%、80.39%、82.45%、43.07%和41.03%.     

Preparative separation of vitexin and isovitexin from pigeonpea extracts with macroporous resins

Vitexin and isovitexin are a pair of isomeric compounds known as the major constituents in pigeonpea leaves and possess various pharmacological activities. In the present study, the preparative separation of vitexin and isovitexin with macroporous resins (Nankai Hecheng S & T, Tianjin, China) was studied. The performance and adsorption characteristics of eight macroporous resins including ADS-5, ADS-7, ADS-8, ADS-11, ADS-17, ADS-21, ADS-31 and ADS-F8 have been evaluated. The research results indicate that ADS-5 resin is most appropriate for the separation of vitexin and isovitexin. Langmuir and Freundlich isotherms were used to describe the interactions between solutes and resin at different temperatures, and the equilibrium experimental data were well fitted to the two isotherms. Column packed with ADS-5 resin was used to perform dynamic adsorption and desorption tests to optimize the separation process. The optimum parameters for adsorption were as follows: the concentration of vitexin and isovitexin in sample solution: 0.22 and 0.40mg/mL, respectively, processing volume: 3 BV, flow rate: 1mL/min, pH 4, temperature: 25 degrees C; for desorption: ethanol-water (40:60, v/v), 5 BV as an eluent, flow rate: 1mL/min. After one run treatment with ADS-5 resin, the contents of vitexin and isovitexin were increased 4.07-fold and 11.52-fold from 0.86%, 1.53% to 3.50% and 17.63%, the recovery yields were 65.03% and 73.99%, respectively. In conclusion, the preparative separation of vitexin and isovitexin can be easily and effectively achieved via adsorption and desorption on ADS-5 resin, and the method can be referenced for the separation of other flavone C-glucosides from herbal materials.     

717型阴离子交换树脂吸附水溶性芳香族有机污染物研究

研究了717型阴离子交换树脂对苯酚、苯甲酸和十二烷基苯磺酸钠(SDBS)等水溶性芳香族污染物吸附过程的基本化学问题.研究结果表明:717型树脂对苯酚、苯甲酸和SDBS的吸附过程均符合Lagergren二级吸附动力学方程,吸附速率均随着温度的升高而加快,吸附表观活化能Ea分别为13.2kJ/mol、59.5kJ/mol和48.1kJ/mol,吸附过程△H0和△S0均为正值,△G0均为负值,吸附能够自发进行;吸附等温模型符合Langmuir等温式;318K时,717型树脂在pH=9.1对SDBS的饱和吸附容量为360mg/g;在pH=10.2,对苯酚和苯甲酸的饱和吸附容量分别为194mg/g和286mg/g.用浓度均为0.5mol/L,体积比为5∶1的NaCl-NaOH混合溶液可快速洗脱树脂上吸附的污染物,洗脱率达98％以上.该树脂对水溶性芳香族污染物吸附容量大,易于再生和循环利用,可用于环境水体中水溶性芳香族有机污染物的吸附治理.