重楼皂甙提取工艺优化与近红外光谱在线质量控制

以滇重楼的根茎为实验材料,重楼甾体总皂甙的提取率为评价指标,运用L16(45)正交试验,考察了皂甙浸出过程中的浸泡时间、乙醇浓度、超声剂量、粗粉质量与浸泡用乙醇体积之比4个因素在4个水平下的工艺过程,筛选出了最佳提取工艺.实验结果表明粗粉(0.45 mm粒径)用30%的乙醇溶液浸泡36 h后,超声30 min,粗粉质量与(浸泡)乙醇的体积比115为最佳提取条件,重楼甾体总皂甙的提取率为9.50%.以近红外漫反射光谱技术为在线监控手段,利用模式识别方法对AB-8树脂分离精制过程中的吸附、杂质洗脱和甾体总皂甙解吸洗脱等工艺过程进行了在线质量监控方法研究,建立了优化的质量可控的分离纯化方法.     

重楼皂甙提取工艺优化与近红外光谱在线质量控制

以滇重楼的根茎为实验材料，重楼甾体总皂甙的提取率为评价指标，运用L16（4^5）正交试验，考察了皂甙浸出过程中的浸泡时间、乙醇浓度、超声剂量、粗粉质量与浸泡用乙醇体积之比4个因素在4个水平下的工艺过程，筛选出了最佳提取工艺。实验结果表明：粗粉（0．45mm粒径）用30％的乙醇溶液浸泡36h后，超声30min，粗粉质量与（浸泡）乙醇的体积比1：15为最佳提取条仲，重楼甾体总皂甙的提取率为9．50％。以近红外漫反射光谱技术为在线监控手段，利用模式识别方法对AB-8树脂分离精制过程中的吸附、杂质洗脱和甾体总皂甙解吸洗脱等工艺过程进行了在线质量监控方法研究，建立了优化的质量可控的分离纯化方法。     

重楼中薯蓣皂甙元的反相高效液相色谱测定

采用高效液相色谱法测定了重楼中薯蓣皂甙元的质量分数。样品先经甲醇提取,再经酸水解,将重楼甾体皂甙转变成薯蓣皂甙元,以ＳｙｍｍｅｔｒｙＣ８柱为色谱柱,以Ｖ（乙腈）∶Ｖ（水）＝７５∶２５溶液为流动相,检测波长２０３ｎｍ,重复性较好,结果令人满意。     

超声波作用下的钛醇盐水解法制备纳米TiO2

近十几年来, 有关二氧化钛光催化性能的研究已引起人们的浓厚兴趣, 在此方面进行了大量研究. 目前, 纳米二氧化钛的制备方法主要有化学沉淀法、溶胶-凝胶法、气相法和水热法等[1,2]. 超声化学是近年来新兴的一门边缘交叉学科, 已被应用于制备具有特殊结构和性能的纳米材料, 如金属[3]、碳化物[4]、氮化物[5]、氧化物[6]、合金[7]以及生物材料[8]等, 但对于超声作用在纳米粒子晶型转变方面的研究报道较少.     

3β,26-二乙酰氧基-5,16-二烯-胆甾-22-酮的合成

云南丰产生物资源薯蓣皂甙元与重楼的活性成分偏诺皂甙元(Ⅰ)、克里普托皂甙元(Ⅱ)以及从非洲南部的虎眼万年青中分离得到的抗肿瘤活性物质OSW-1(Ⅲ)[1,2]具有相同的骨架,若利用薯蓣皂甙元完整碳骨架合成化合物Ⅰ～Ⅲ,其关键是在15,16位引入一个碳碳双键[3],再经结构修饰可实现Ⅰ～Ⅲ的合成,本文报道可用于合成上述化合物Ⅰ～Ⅲ的关键中间体3β,26-二乙酰氧基-5,16-二烯-胆甾-22-酮的合成,产物并经IR,1H NMR,13C NMR,EI-MS,HRMS所证实,总收率在30%左右.     

人参花蕾中四环三萜皂甙的化学研究

近年来,寻找人参(Panaxginseng C. A. Meyer)的主要有效成分皂甙类物质的研究十分活跃^[1,2].我们曾报道人参花蕾中含有大量的人参皂甙^[3],本文从中分离出两种四环三萜皂甙,通过测定它们的物理常数、制备衍生物、进行光谱分析并与已知化合物直接对照,鉴定了它们的化学结构分别为(1)人参皂甙Rb₂(ginsenoside-Rb₂)和(2)20-葡萄糖-人参皂甙Rf(20-glucoginsenoside-Rf).后者从人参花蕾中分离鉴定未见报道.     

柴胡中柴胡皂甙a的超声辅助溶剂提取

以溶剂提取法为基础,以超声波为辅助手段,对柴胡中的有效成分进行了提取.通过对提取液中柴胡皂甙a量的测定,研究了超声功率、提取温度、提取时间和样品浸渍时间等条件对提取效果的影响,优选出超声辅助溶剂提取的最佳条件为超声功率50%、提取温度50 ℃、提取时间20 min、样品浸渍时间24 h.实验结果表明,超声辅助溶剂提取比普通的溶剂提取具有更高的提取效率.     

气相色谱法测定高硫化氢含量气体中微量有机硫化合物

正近年来,我国煤化工的研究热点主要集中在煤制甲醇[1]、煤制烯烃[2]、煤制油[3]、煤制乙二醇[4]等煤制化工产品领域。在各类煤制化工产品的合成过程中,均需要使用煤气化净化合成气作为原料气,其中硫的物质的量占比应不高于5.0×10-3。煤气化方法主要包括德士古水煤浆加压气化法[5]和德国西门子GSP气化法[6-7]。在进行煤气化时,原煤中的杂质硫会反应生成硫化氢、羰基硫化物等含硫副产物[8],物质的量占比约为0.5%[9],     

纳米银的电化学合成

纳米颗粒因具有量子尺寸效应、表面效应和宏观量子隧道效应等不同于晶态体材料和单个分子的固有特性 ,显示出体材料不具备的导电特性、光电特性、光催化能力及随粒径变化的吸收或发射光谱 ,已被用于各种发光与显示装置[1] .其制备的化学方法主要有溶胶 -凝胶法、微乳法、化学沉淀法和醇解法等 [2 ] .近年来 ,新发展出一种电化学合成纳米粒子的方法 ,如 Braun等 [3]利用 DNA模板电化学合成了银纳米线 ,Yu等[4 ] 用电化学合成了金纳米棒 ,Zhu等[5] 利用超声电化学合成了半导体 Pb Se纳米粒子 ,Amigo等 [6 ]用电化学方法合成了 Fe-Sr氧化…     

小体积进样-离子色谱法测定石膏中三氧化硫

石膏是一种用途广泛的工业材料和建筑材料,是生产石膏胶凝材料和石膏建筑制品的主要原料,也是硅酸盐水泥的缓凝剂。工业石膏一般含有一定量的杂质,如碳酸钙、碳酸镁、氯化镁、氯化钠等,因此在用石膏进行生产时都需控制其纯度。通常检测石膏的纯度是测定其中的三氧化硫含量。应用较多的方法有硫酸钡重量法[1-2]、容量法[3]和离子交换法[4]等,这些方法各有优缺点,其中国家标准GB/T5484-2000[1]中规定的硫酸钡重量法是一种比较经     

云南重楼中的新甾体皂苷

从云南重楼Paris polyphylla Sm. var. yunnanensis(France. )Hand.-Mazz.的干燥根茎中分离鉴定了4个甾体皂苷(1~4), 其中化合物1是新化合物, 采用波谱技术鉴定其结构为24-O-β-D-吡喃半乳糖基-(23S,24S)-螺甾-5, 25(27)-二烯-1β,3β,23,24-四醇-1-O-β-D-吡喃木糖基(1→6)-β-D-吡喃葡萄糖基(1→3)[α-L-吡喃鼠李糖基(1→2)]-β-D-吡喃葡萄糖苷.     

Natural Deep Eutectic Solvents for the Extraction of Bioactive Steroidal Saponins from Dioscoreae Nipponicae Rhizoma

In the present study, a simple and environmentally friendly extraction method based on natural deep eutectic solvents (NADESs) was established to extract four bioactive steroidal saponins from Dioscoreae Nipponicae Rhizoma (DNR). A total of twenty-one types of choline chloride, betaine, and L-proline based NADESs were tailored, and the NADES composed of 1:1 molar ratio of choline chloride and malonic acid showed the best extraction efficiency for the four steroidal saponins compared with other NADESs. Then, the extraction parameters for extraction of steroidal saponins by selected tailor-made NADES were optimized using response surface methodology and the optimal extraction conditions are extraction time, 23.5 min; liquid–solid ratio, 57.5 mL/g; and water content, 54%. The microstructure of the DNR powder before and after ultrasonic extraction by conventional solvents (water and methanol) and the selected NADES were observed using field emission scanning electron microscope. In addition, the four steroidal saponins were recovered from NADESs by D101 macroporous resin with a satisfactory recovery yield between 67.27% and 79.90%. The present research demonstrates that NADESs are a suitable green media for the extraction of the bioactive steroidal saponins from DNR, and have a great potential as possible alternatives to organic solvents for efficiently extracting bioactive compounds from natural products.     

Negative-Pressure Cavitation Extraction of Four Main Vinca Alkaloids from <em>Catharanthus </em><em>r</em><em>oseus</em> Leaves

In the present study, an improved method termed negative-pressure cavitation extraction (NPCE) followed by reverse phase high-performance liquid chromatography (RP-HPLC) was developed for the extraction and quantification of vindoline (VDL), catharanthine (CTR), vincristine (VCR) and vinblastine (VLB) from Catharanthus roseus leaves. The optimized method employed 60-mesh particles, 80% ethanol, a negative pressure of -0.075 MPa, a solid to liquid ratio of 1:20, 30 min of extraction and three extraction cycles. Under these optimized conditions, the extraction yields of VDL, CTR, VCR and VLB are 0.5783, 0.2843, 0.018 and 0.126 mg/g DW, respectively. These extraction yields are equivalent to those from the well-known ultrasonic extraction method and higher than the yields from maceration extraction and heating reflux extraction. Our results suggest that NPCE-RP-HPLC represents an excellent alternative for the extraction and quantification of vinca alkaloids for pilot- and industrial-scale applications.     

Application of accelerated solvent extraction to the investigation of saikosaponins from the roots of Bupleurum falcatum

Accelerated solvent extraction (ASE) was applied to the extraction of saikosaponin a, saikosaponin c and saikosaponin d from the roots of Bupleurum falcatum. Main extraction parameters such as the extraction solvents, extraction temperature and static extraction time were investigated and optimized. The optimized procedure employed 70% methanol as extraction solvent, 120°C of extraction temperature, 10 min of static extraction time, 60% of flush volume and the extraction recoveries of the three compounds were near to 100% with one extraction cycle. The extracted samples were analyzed by HPLC with UV detector. The HPLC conditions were as follows: Hypersil ODS2 (4.6 mm×250 mm, 5 μm) column, acetonitrile and water as mobile phase, flow rate of 1.0 mL/min, UV detection wavelength of 204 nm and injection volume of 20 μL. Compared with the traditional methods including heat‐reflux extraction and ultrasonic‐assisted extraction, the proposed ASE method was more efficient and faster to be operated. The results indicated that ASE was an alternative method for extracting saikosaponins from the roots of B. falcatum.     

Optimization of microwave-assisted extraction for alizarin and purpurin in Rubiaceae plants and its comparison with conventional extraction methods

A simple and rapid microwave-assisted extraction (MAE) procedure was developed and optimized for two common color pigments, alizarin and purpurin, in various samples of Rubiaceae plants. Several variables that can potentially affect the extraction efficiency, namely temperature, methanol concentration in the extractant mixture, time, and solvent volume were optimized by means of a central composite design approach. The results suggest that temperature and methanol concentration in the solvent mixture are statistically the most significant factors. The separation and quantitative determination of the pigments was carried out in less than 6 min by a developed high-performance liquid chromatographic method with UV detection at 250 nm. Under optimum operating conditions, MAE showed significantly higher recoveries than those obtained by the conventional extraction methods (ultrasonic and reflux extraction), ranging from 84 to 94%. In addition, a drastic reduction of the extraction time (20 min versus 6 h) and solvent consumption (20 versus 100 mL) was achieved with a reproducibility (RSDs < 10%) comparable with that provided by the reflux extraction as a reference method.     

Extraction and identification of steroidal saponins from Polygonatum cyrtonema Hua using natural deep eutectic solvent-synergistic quartz sand-assisted extraction method

In this study, quartz sand with particularly sharp nanoscale edges acted like a nanoscale knife physically cut cells of Polygonatum cyrtonema Hua into nanosized particles and was synergized with natural deep eutectic solvent to extract steroidal saponins of Polygonatum cyrtonema Hua. The natural deep eutectic solvent (choline chloride-lactic acid)-synergistic quartz sand-assisted extraction was optimized using response surface methodology. The steroidal saponins purified with AB-8 macroporous resin were identified using ultra-high-performance liquid chromatography-triple time of flight mass spectrometry. The results showed that the experimental total saponins content value (36.97 ± 0.12 mg dioscin equivalent/g dry weight) at optimal extraction conditions with a temperature of 68°C, a rotational speed of 20 400 rpm, shear time of 4.3 min, the liquid-solid ratio of 38 ml/g, was close to the maximum possible theoretical value (36.64 mg dioscin equivalent/g dry weight). A total of 20 steroidal saponins were identified, among which the content of (25R)-Kingianoside E was the highest (102.66 ± 3.47 mg/g). Furthermore, a new steroid saponin (3β,25S)-26-(β-D-glucopyranosyloxy)-22-hydroxyfurost-5-en-3-yl 4-O-β-D-glucopyranosyl-β-D-galactopyranoside+Glc was found for the first time. These results revealed that natural deep eutectic solvent-synergistic quartz sand-assisted extraction was an efficient and green method to extract a variety of steroidal saponins.     

Chromatographic determination of plant saponins

The methods used for saponin determination in plant materials are presented. It is emphasised that the biological and spectrophotomeric methods still being used for saponin determination provide, to some extent, valuable results on saponin concentrations in plant material. However, since they are sensitive to the structural variation of individual saponins they should be standardized with saponin mixtures isolated from the plant species in which the concentration is measured. However, one plant species may contain some saponins which can be determined with a biological test and others which cannot. That is why biological and colorimetric determinations do not provide accurate data and have to be recognized as approximate. Thin-layer chromatography on normal and reversed-phases (TLC, HPTLC, 2D-TLC) provides excellent qualitative information and in combination with on-line coupling of a computer with dual-wavelength flying-spot scanner and two-dimensional analytical software can be used for routine determination of saponins in plant material. The densitometry of saponins has been very sensitive, however, to plate quality, spraying technique and the heating time and therefore appropriate saponin standards have to be run in parallel with the sample. Gas-liquid chromatography has limited application for determination since saponins are quite big molecules and are not volatile compounds. Thus, there are only few applications of GC for determination of intact saponins. The method has been used for determination of TMS, acetyl or methyl derivatives of an aglycones released during saponin hydrolysis. However, structurally different saponins show different rates of hydrolysis and precise optimisation of hydrolysis conditions is essential. Besides, during hydrolysis a number of artefacts can be formed which can influence the final results. High performance liquid chromatography on reversed-phase columns remains the best technique for saponin determination and is the most-widely used method for this group of compounds. However, the lack of chromophores allowing detection in UV, limits the choice of gradient and detection method. The pre-column derivatisation with benzoyl chloride, coumarin or 4-bromophenacyl bromide has been used successfully in some cases allowing UV detection of separation. Standardisation and identification of the peaks in HPLC chromatograms has been based on comparison of the retention times with those observed for authentic standards. But new hyphenated techniques, combining HPLC with mass spectrometry and nuclear magnetic resonance are developing rapidly and allow on-line identification of separated saponins. Capillary electrophoresis has been applied for saponin determination only in a limited number of cases and this method is still being developed.     

Optimization of microwave-assisted solvent extraction for volatile organic acids in tobacco and its comparison with conventional extraction methods

In the present study, a new method using microwave-assisted solvent extraction (MASE) technique followed directly GC analysis was developed for the extraction of volatile organic acids (VOAs) in tobacco. The MASE conditions (heating time, volume of extracting solvent and extraction temperature) were optimized by means of an orthogonal array design (OAD) procedure. The results suggested that extractant, temperature and heating time were statistically the most significant factors. The extracts were directly analyzed with capillary GC operating in splitless-injection mode on an Agilent HP-FFAP capillary column. Under optimum operating conditions, MASE showed significantly better recoveries than those obtained by the conventional extraction method (ultrasonic and reflux extraction), ranging from 90.6% to 103.2%. In addition, a drastic reduction of the extraction time (20 min versus 4 h) and solvent consumption (20 mL versus 100 mL) was achieved with an outstanding reproducibility (CV ≤5%).     

金银花绿原酸提取方法研究

采用高效液相色谱法测定金银花中绿原酸的含量,通过热回流法优化金银花绿原酸提取条件并进行正交试验分析. 试验结果表明,金银花中绿原酸最佳提取条件为乙醇体积分数80%、提取温度100 ℃、料液比1∶20 （g/mL）、提取时间2 h时,绿原酸提取率为7.1%. 方法分析准确、操作简便、设备要求低,可用作金银花的质量控制和开发利用.     

百合皂甙多糖的连续提取工艺研究

皂甙和多糖是药用百合的两个主要有效成份。文章用正交实验法对百合皂甙多糖的提取工艺进行了研究。优选出简便可靠且适合工业化生产的连续提取百合皂甙多糖的工艺。百合皂甙的最佳提取工艺条件是:温度为70℃,乙醇浓度为80%,固液比例为1:6,提取时间3h,提取次数3次。多糖的最佳提取工艺条件是:温度为95℃,固液比例为1:10,提取时间3h,提取次数2次。用AB-8大孔吸附树脂分离、乙醚-丙酮分步沉淀得到纯百合皂甙。