紫草中活性成分的非极性溶剂动态微波提取及高效液相色谱法测定

用非极性溶剂动态微波辅助提取,高效液相色谱法测定紫草中的紫草素和β,β′-二甲基丙烯酰紫草素.考察了微波吸收介质类型、提取溶剂种类、提取溶剂流速、微波功率和样品粒度对提取产率的影响,优化提取参数.在优化条件下,将所建立的方法与超声提取和索氏提取相比,所得紫草素和β,β′-二甲基丙烯酰紫草素的产率相差不大,但本文所建立的方法所需提取时间短(5min)、溶剂消耗少(10mL).与极性溶剂动态微波辅助提取相比,提取产率大幅度提高.结果说明,所建立的方法是一种有效的提取中草药中一些活性成分的方法,特别是对于一些在非极性溶剂中有更高溶解度的化合物,此方法更具优势.     

固体微波介质加热快速提取新鲜橘皮中挥发油组分

对传统微波加热模式进行了改进,以具有良好微波吸收性能的微波吸收固体介质取代传统溶剂和水,将其加入到新鲜样品的提取体系,达到快速升温的目的.将改进的微波辅助无溶剂法应用于提取新鲜植物样品中挥发油组分,并考察了3种微波吸收介质(羰基铁粉、石墨粉和活性炭粉)对提取结果的影响.结果证明:对于新鲜样品,除活性炭粉无法使用外,羰基铁粉和石墨粉均适用.在20 g微波吸收介质及85 W微波功率的加热作用下,仅需30 min即可将100 g样品中的挥发油提取完全.通过与传统微波辅助无溶剂法、微波辅助水蒸馏法和传统水蒸馏法比较,改进的微波辅助无溶剂法具有提取时间短(30 min)、耗电量小(0.43 kW · h/kg)等优点,且所得挥发油组分无明显差别.此外,还考察了烘干过程对橘皮挥发油组成的影响,发现橘皮挥发油的组成受烘干影响较大.     

微波辅助条件下鱼腥草中癸酰乙醛的高效提取

以乙酸乙酯为溶剂,在微波辅助条件下提取鱼腥草挥发油,考察了微波温度、功率及时间对鱼腥草挥发油提取率及鱼腥草素(癸酰乙醛)含量的影响,探讨了鱼腥草挥发油储存过程中癸酰乙醛的化学转化。研究发现,在温度80℃、功率1 000 W及时间12min的微波辅助条件下,鱼腥草挥发油的提取率高达0.66%,挥发油中癸酰乙醛的含量高达60.78%。在微波辅助条件下,较低的提取温度及快速提取有效避免了癸酰乙醛的氧化分解是其高效提取的根本原因,鱼腥草挥发油中存在癸酰乙醛与其二聚物的动态平衡是癸酰乙醛长时间保持稳定的主要原因。     

微波辅助提取-电感耦合等离子体质谱法测定海产品中总有机锡

建立了微波辅助提取-电感耦合等离子体质谱法(MAE-ICP-MS)测定海产品中总有机锡含量的方法。以丙酮-正己烷(体积比3∶1)为溶剂,微波辅助提取海产品中的有机锡,采用ICP-MS测定。微波提取条件如提取剂用量、溶剂比例、提取温度及提取时间采用正交设计进行优化。方法检出限为0.47ng/g,平均加标回收率为92.7%～106%,相对标准偏差(RSD)在1.18%～2.38%之间。该法可应用于虾米、淡菜、海砺干、蛤砺干、海星等海产品中总有机锡的测定。     

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.     

非极性溶剂微波萃取-气相色谱-质谱法测定白豆蔻中挥发油成分

提出了非极性溶剂微波萃取-气相色谱-质谱法测定白豆蔻中的挥发油成分的方法。优化的试验条件如下:①微波吸收介质为0.35g石墨粉;②提取溶剂为正己烷;③样品质量与溶剂容积之比为2g比25mL;④提取时间为30min。在气相色谱分离中用DB-5石英毛细管柱为固定相,在质谱分析中采用全扫描检测模式。以α-甲基苯甲醇丙酸酯为内标物。方法用于白豆蔻样品的分析,共鉴定出60种挥发性化学成分,主要化合物为桉油精(70.34%)、β-蒎烯(6.81%)、α-松油醇(3.36%)和α-蒎烯(2.54%)等。     

微波辅助蒸汽蒸馏提取-气相色谱-质谱法测定矮化芳樟枝叶挥发油成分

采用微波辅助蒸汽蒸馏提取法对矮化芳樟枝或叶中挥发油进行提取,用气相色谱-质谱法测定其中的挥发油成分。所得结果与传统蒸汽蒸馏提取法数据对比,两种方法所得枝叶挥发油主要成分和含量基本相同;但微波辅助蒸汽蒸馏提取法仅需37.5min即可达到最高提取率。     

微波辅助提取-GC/MS联用分析苍耳子中油脂成分的研究

采用微波辅助提取-GC/MS联用分析苍耳子中的油脂成分.以V(环已烷):V(丙酮)=1:1为提取溶剂,优化了微波辅助提取的条件.以正二十烷为内标,鉴定出了13种油脂成分,各组分相对保留时间的相对标准偏差(RSD)小于0.15%,相对峰面积的RSD＜3.0%.对不同批次以及不同产地的苍耳子样品进行了对比研究.该方法可用于苍耳子的鉴定和质量控制.     

赤芍及其相关药对中挥发油成分的研究

运用微波辅助萃取从赤芍及其相关药对中提取了挥发油,通过GC-MS检测,确定了主要成分及相对含量。结果表明,赤芍挥发油主要成分是水杨醛,在赤芍-川芎药对挥发油中它仍占较大比重。微波辅助萃取大大缩短了提取时间和提高了提取效率。     

减压提取与常压提取柴胡挥发油品质比较

对比减压和常压条件下提取的柴胡挥发油在成分、含量及药效方面的差异,考察挥发油的品质,优选提取方法.采用气相色谱-质谱联用(GC-MS)法分析柴胡挥发油成分及其相对含量,再采用气相色谱法建立挥发油中己醛、庚醛、正辛醛和反式-2,4-癸二烯醛的含量检测方法,测定不同压力下提取的柴胡挥发油有效成分含量,通过背部皮下注射酵母混...     

Non-polar Solvent Microwave-Assisted Extraction of Volatile Constituents from Dried Zingiber Officinale Rosc.

A new method, non-polar solvent microwave-assisted extraction （NPSMAE）, was applied to the extraction of essential oil from Zingiber officinale Rosc. in closed-vessel system. By adding microwave absorption mediumcarbonyl iron powders （CIP） into extraction system, the essential oil was extracted by the non-polar solvent （ether） which can be heated by CIP. The constituents of essential oil obtained by NPSMAE were comparable with those obtained by hydrodistillation （HD） by GC-MS analysis, which indicates that NPSMAE is a feasible way to extract essential oil from dried plant materials. The NPSMAE took much less extraction time （5 min） than HD （180 min）, and its extraction efficiency was much higher than that of conventional polar solvent microwave-assisted extraction （PSMAE） and mixed solvent microwave-assisted extraction （MSMAE）. It can be a good alternative for the extraction of volatile constituents from dried plant samples.     

改进的微波辅助无溶剂法提取薄荷和陈皮中的挥发油组分

An improved solvent free microwave extraction, in which a kind of microwave absorption medium （carbonyl iron powder） was used, was applied to the extraction of essential oil from dried menthol mint and orange peel without addition of any solvent and pretreatment. It took much less time of extraction （30 min） than microwave-assisted hydrodistillation （90 min） and conventional hydrodistillation （180 min）. The kinds of chemical compositions in essential oil extracted by different methods were almost the same and such improved solvent free microwave extraction can be a feasible way in extraction of essential oil from dried plant materials.     

Application of factorial design and Box-Behnken matrix in the optimisation of a microwave-assisted extraction of essential oils from Salvia mirzayanii

Essential oil of Salvia mirzayanii cultivated in Iran was obtained by microwave assisted extraction (MAE) procedures. The essential oil was analysed by capillary gas chromatography using flame ionisation and mass spectrometric detections. The effects of different parameters, such as microwave power, temperature, time and type of solvent on the MAE of Salvia mirzayanii oil were investigated. Results of the two-level fractional factorial design (2(4-1)) based on an analysis of variance demonstrated that only the power, temperature and type of solvent were statistically significant. Optimal conditions for the extraction of essential oils were obtained by using Box-Behnken design. For optimum recovery of essential oil the variables power, temperature and solvent values were 115?W, 50°C and 14?s, respectively. Under the optimised experimental conditions, the extraction yield of microwave assisted extraction was 11.2% (w/w).     

Microwave-Assisted Extraction/Dispersive Liquid–Liquid Microextraction Coupled with DSI-GC-IT/MS for Analysis of Essential Oil from Three Species of Cardamom

A novel method of microwave-assisted extraction coupled with polyethylene Pasteur-pipette-based dispersive liquid–liquid microextraction applying low-density organic solvent (MAE-LDS-DLLME) was successfully developed for extraction and preconcentration of essential oil from three species of cardamom (Semen Alpiniae Katsumadai, Fructus Amomi Rotundus, and Semen Myristicae). The essential oil was analyzed by gas chromatography-ion trap/mass spectrometry (GC-IT/MS) using a ChromatoProbe direct sample introduction (DSI) device. The effects of various parameters affecting the extraction process, such as the type of extraction solvent and dispersive solvent, ionic strength, microwave power, and irradiation time, were investigated thoroughly and optimized. The optimal conditions were extraction solvent of toluene, dispersive solvent of methanol, microwave power of 80 W, irradiation time of 4.0 min, plant material amount of 0.1 g, and no addition of salt. Compared with hydrodistillation, MAE-DLLME-DSI-GC–MS is a simple, rapid, low-cost, efficient, and environmentally friendly method, and the essential oil contains higher amounts of oxygenated compounds, which play an important and valuable role in terms of their contribution to the fragrance of the essential oil. In this work, we also studied the main components of the three varieties of cardamom. Qualitative and quantitative differences in the components of the three essential oils were found to be present. Based on comparison of the main bioactive compounds of essential oil, a significant difference was found between Semen Alpiniae Katsumadai or Fructus Amomi Rotundus and Semen Myristicae. This study also provides a new approach for quality assessment of traditional Chinese medicines.     

Water as a green solvent combined with different techniques for extraction of essential oil from lavender flowers

Using water as a green solvent with a variable geometry makes use of physical and chemical phenomena that are fundamentally different from those applied in conventional extraction techniques such as hydro-distillation, steam distillation or solvent extraction. Advantages and drawbacks of using water as a solvent with different physical and chemical states have been compared. A total of ten extraction techniques: hydro-distillation (HD), steam distillation (SD), turbo-hydro-distillation (THD), salt-hydro-distillation (NaCL-HD), enzyme-hydro-distillation (Enzyme-HD), micelle-hydro-distillation (Micelle-HD), ultrasound-hydro-distillation (US-HD) or subcritical water-hydro-distillation (SW-HD), solvent-free microwave extraction (SFME) and microwave steam distillation (MSD) were used to extract the essential oil from lavender (Lavandula L.) and their results were compared. The quantity was measured by the yield of essential oil and the quality was evaluated using the oil composition especially the content of linalyl acetate, linalool and terpin-4-ol compared with the corresponding control sample: Hydro-distillation. For environmentally friendly of the process: extraction time, total energy consumption and CO₂ emission were considered and compared with conventional hydro-distillation. The mechanism explaining the linalyl acetate degradation has been resolved by using COSMO-RS software. Based on the present experimental conditions, it is recommended that lavender oil may be produced preferably by steam distillation assisted by microwave extraction to reduce the by-product formation by various chemical reactions and to get better oil recoveries.     

Hydrodistillation-headspace solvent microextraction, a new method for analysis of the essential oil components of Lavandula angustifolia Mill

A new method involving concurrent headspace solvent microextraction combined with continuous hydrodistillation (HD-HSME) for the extraction and pre-concentration of the essential oil of Lavandula angustifolia Mill. into a microdrop is developed. A microdrop of n-hexadecane containing n-heptadecane (as internal standard) extruded from the needle tip of a gas chromatographic syringe was inserted into the headspace above the plant sample. After extraction for an optimized time, the microdrop was retracted into the syringe and injected directly into a GC injection port. The effects of the type of extracting solvent, sample mass, microdrop volume and extraction time on HD-HSME efficiency were investigated and optimized. Using this method, thirty-six compounds were extracted and identified. Linalool (32.8%), linalyl acetate (17.6%), lavandulyl acetate (15.9%), alpha-terpineol (6.7%) and geranyl acetate (5.0%) were found to be the major constituents. To the best of our knowledge this is the first report on the use of continuous headspace solvent microextraction coupled with hydrodistillation for investigation of essential oil components.     

Extraction of essential oil from Pimpinella anisum using supercritical carbon dioxide and comparison with hydrodistillation

Supercritical fluid extraction (SFE) of essential oil from Pimpinella anisum, using carbon dioxide as a solvent is presented in this work. An orthogonal array design OA9 (3(4)) was applied to select the optimum extraction condition. The effects of pressure, temperature, dynamic extraction time and methanol volume on the extraction efficiency were investigated by the three-level orthogonal array design. Results show that pressure has a significant effect on the extraction efficiency. The extract obtained from P. anisum by using supercritical fluid extraction was compared with the essential oil obtained by hydrodistillation, considering both quantity and quality of the product. SFE products were found to be of markedly different composition, compared with the corresponding hydrodistilated oil. The total amount of extractable substances obtained in SFE (7.5%) is higher than that obtained by hydrodistillation (3.1%) and SFE is faster than hydrodistillation method.     

Optimization of an accelerated solvent extraction dispersive liquid–liquid microextraction method for the separation and determination of essential oil from Ligusticum chuanxiong Hort by gas chromatography with mass spectrometry

In this study, an accelerated solvent extraction dispersive liquid–liquid microextraction coupled with gas chromatography and mass spectrometry was established and employed for the extraction, concentration and analysis of essential oil constituents from Ligusticum chuanxiong Hort. Response surface methodology was performed to optimize the key parameters in accelerated solvent extraction on the extraction efficiency, and key parameters in dispersive liquid–liquid microextraction were discussed as well. Two representative constituents in Ligusticum chuanxiong Hort, (Z)‐ligustilide and n‐butylphthalide, were quantitatively analyzed. It was shown that the qualitative result of the accelerated solvent extraction dispersive liquid–liquid microextraction approach was in good agreement with that of hydro‐distillation, whereas the proposed approach took far less extraction time (30 min), consumed less plant material (usually <1 g, 0.01 g for this study) and solvent (<20 mL) than the conventional system. To sum up, the proposed method could be recommended as a new approach in the extraction and analysis of essential oil.     

Rapid determination of essential oil compounds in Artemisia Selengensis Turcz by gas chromatography-mass spectrometry with microwave distillation and simultaneous solid-phase microextraction

In the work, for the first time, two solvent-free sample preparation techniques of microwave distillation (MD) and solid-phase microextraction (SPME) were combined, and developed for determination of essential oil compounds in traditional Chinese medicine (TCM). Using the proposed method, isolation, extraction and concentration of TCM essential oil compounds can be carried out in a single step. To demonstrate its feasibility, MD-SPME was compared with a conventional technique, steam distillation (SD), for gas chromatography-mass spectrometry (GC-MS) analysis of essential oil compounds in a TCM, Artemisia Selengensis Turcz. Forty-nine compounds in the TCM were separated and identified by the present method, while only 26 compounds were detected by SD method. Relative standard deviation (R.S.D.) values less than 9% show that the present method has good precision. The SD method required long time (6 h) to isolate of the essential oil, and large amount of organic solvent for further extraction, while MD-SPME needed little time (only 3 min) to prepare sample, and no organic solvent. These results show that MD-SPME-GC-MS is a simple, rapid and solvent-free method for determination of TCM essential oil.     

Headspace single drop microextraction coupled with microwave extraction of essential oil from plant materials

Headspace single drop microextraction (HS-SDME) coupled with microwave extraction (ME) was developed and applied to the extraction of the essential oil from dried Syzygium aromaticum (L.) Merr. et Perry and Cuminum cyminum L. The operational parameters, such as microdrop volume, microwave absorption medium (MAM), extraction time, and microwave power were optimized. Ten microliters of decane was used as the microextraction solvent. Ionic liquid and carbonyl iron powder were used as MAM. The extraction time was less than 7 min at the microwave power of 440 W. The proposed method was compared with hydrodistillation (HD). There were no obvious differences in the constituents of essential oils obtained by the two methods.