金属离子的超临界流体萃取技术的进展

超临界流体萃取技术在分离方面发展迅速,应用前景十分广泛。文中综述了超临界流体技术的萃取机理及对金属离子萃取的研究。     

超临界流体技术在萃取中的应用简介

超临界流体萃取技术具有许多传统技术所没有的快速、高效、高选择性、低能耗等优点,特别是超临界流体的特性是它可以代替高毒有机溶剂做反应介质,符合绿色化学的要求。本文综述了超临界流体的特性,介绍了超临界流体萃取的原理,归纳了超临界流体萃取的应用现状,并介绍了超临界流体的其他领域应用概况。     

自制超临界流体萃取仪操作条件的优化及其应用

超临界流体萃取是近年来发展起来的一种新的分离技术。本文使用自己研制的超临界流体萃取仪对吸附有痕量正构烷烃的Ａｌ２Ｏ３进行萃取，对各种操作条件进行优化。并对卢柑皮及生姜样品进行初步的萃取分析。结果证明该仪器设计合理，具有操作简便、高效、自动化程度高的优点，为复杂样品中痕量组分的萃取分析奠定了基础。     

白术挥发性成分的超临界流体萃取及其分析

采用超临界流体萃取白术挥发油成分,对萃取条件进行优化,并用气相色谱、气相色谱－质谱分析鉴定出超临界流体萃了的挥发油中22个化合物。最佳的超临界流体萃取条件为压力22.0MPa,温度60℃,0.5mL乙醇作改性,先静态萃取10min(CO2用量2.0mL),再动态萃取40min(CO2流速为0.3mL/min)。将超临界流体萃取与水蒸气蒸馏进行对比,水蒸气蒸馏5h的油收率仅为超临界流体萃取1h油收率的10.32%,证明超临界流体萃取替代传统萃取的必要性。     

超临界流体萃取在甘草酸分析中的应用

对超临界流体萃取的影响因素进行了研究，并将其用于甘草酸的分析，找到了适宜的萃取条件，并与溶剂萃取方法进行了比较。     

环境模拟样品中多环芳烃的超临界流体萃取：Ⅰ.利用正交设…

采用正交设计实验方法，研究了从环境模拟样品中超临界流体萃取多环芳烃的最佳萃取条件。着重考察了超临界流体的压力、温度和用量等对萃取效率的影响。     

超临界流体(SCF)技术进展

超临界流体因其表现出的特殊的物质溶解性，且这些特性在临界点附近因温度和压力的微小变化可发生较大的变化，故被用作物质的良溶剂而广泛地应用于萃取，ＲＥＳＳ、ＳＡＳ过程和超临界高分子合成过程中。     

醌类化合物的超临界流体萃取研究进展

综述了国内近20年来超临界流体萃取技术应用于醌类化合物分离的研究进展,重点介绍了超临界流体萃取技术在中草药中醌类化合物的分析测定方面的应用,分析了影响醌类成分提取效果的主要因素,优化萃取温度和萃取压力能够改善琨类化合物的分离效果,夹带剂的使用则有效地提高了超临界流体的萃取能力。     

超临界CO2流体萃取重金属的研究进展

超临界CO2I充体与金属配合技术相结合开辟了重金属萃取的新途径,本文介绍了超临界CO2流体萃取重金属的研究现状,总结了影响萃因素,并对未来的发展趋势作了展望。     

环境模拟样品中多环芳烃的超临界流体萃取I．利用正交设计选择最佳萃取条件

采用正交设计实验方法，研究了从环境模拟样品中超临界流体萃取（ＳＦＥ）多环芳烃（ＰＡＨ）的最佳萃取条件。着重考察了超临界流体的压力、温度和用量等对萃取效率的影响。结果表明，压力的影响居第一位，温度影响次之，超临界ＣＯ２的用量的影响居第三位。建立了选择超临界流体萃取条件的简单方法     

Quantitative analysis of polymer additives in low density polyethylene using supercritical fluid extraction/supercritical fluid chromatography

Analysis of low concentration polymer additives has been a challenging problem. The commonly used methods of analysis involve the initial extraction of polymer additives with solvents, often in a Soxhlet apparatus, followed by liquid, size exclusion, or gas chromatography. This paper describes the on-line super-critical fluid extraction (SFE)-supercritical fluid chromatographic (SFC) determination of different additives from low density polyethylene. Cryogenic collection was used as an interface between SFE and SFC to focus the extraction eluate before transfer to an analytical SFC column for quantitative analysis.     

Improved SFE recovery of trace analytes from liver using an integral micrometering valve–SPE column holder assembly

A novel integral restrictor–collector has been designed for use with a conventional supercritical fluid extraction (SFE) apparatus. The assembly reduces the path length between a micrometering valve and collector (a solid phase extraction (SPE) column), obviating the need for the complicated tubing and connectors usually associated with such devices. Also described is a heating-block assembly which encases the micrometering valve and provides uniform heating of the valve during extraction. The valve–SPE column assembly was part of a system used to perform the first reported SFE multi-residue drug recovery from fortified liver. Extractions used carbon dioxide pressurized to 690 bar as the supercritical fluid. Flow rates of expanded gas through the SPE columns were 3–4 L/min with concomitant quantitative trapping of the analytes on the sorbent bed. After SFE the three nitrobenzamide antimicrobial drug residues from the liver were eluted from the SPE columns by off-line analysis. The results demonstrated that losses of trace level analytes in tissue may be significantly reduced by including an integral metering valve-collector assembly as part of the SFE apparatus.     

Analysis of Organic Pollutants in Aqueous Samples by Supercritical Fluid Extraction Combined with Solid Phase Adsorption

The application of supercritical fluid extraction (SFE) to prepare samples in analytical laboratories is a rapidly expanding area. In comparison with traditional extraction methods, SFE have many advantages, such as short time, low consumption, low pollution, high precision and high selectivity. SFE of analytes from aqueous samples has received little attention as compared with the SFE of solid samples. Since it is difficult to prevent the coextraction of water with the contaminants, which would result in the plugging of the restrictor, generally, SFE is combined with solid phase adsorption (SPA) in treating aqueous samples.     

Comparison of various extraction techniques for isolation and determination of isoflavonoids in plants

In the present paper, the following extraction techniques have been used for extracting isoflavonoids from the species Matricaria recutita, Rosmarinus officinalis, Foeniculum vulgare, and Agrimonia eupatoria L.: supercritical fluid extraction (SFE), pressurized fluid extraction, matrix solid phase dispersion, ultrasonic extraction in an ultrasonic bath (USE) and by means of an ultrasonic homogeniser (HOM), extraction by means of Soxhlet apparatus (SOX), and solid phase extraction. Experimental optimization of all techniques has been carried out using a soybean flour. Subsequent analyses of the extracts were carried out by liquid chromatography with UV detection. The maximum yields of daidzein and genistein were obtained by extraction with the SOX, USE, and HOM techniques. The maximum yields of apigenin and biochanin A from herb samples were obtained by SFE.     

A Unified Sample Preparation System for Extraction of Various Analyte/Matrix Combinations

A supercritical fluid extraction/enhanced solvent extraction system (SFE/ESE) was used to remove polar and non-polar analytes from various matrices. Extraction of environmental pollutants from soil, additives from low density polyethylene, sulfa drugs from animal tissue, and drug from tablet was performed using both SFE and ESE. Results showed that a single instrumental system can be used to perform both ESE with organic solvents and SFE with carbon dioxide-based fluids. Each method has its own unique advantages and applications. The ability to carry out both solvent extraction and supercritical fluid extraction with one system has obvious economical advantages.     

超临界流体萃取与其它分析技术的联用

用超临界流体萑取进行分析样品处理，有快速，高效，低消耗，污染少等优点。本文对ＳＦＥ的原理，特点，与其它技术的联用及其在分析化学诸领域的应用作了综述，其中重点介绍了ＳＦＥ与色谱技术的在线联用，内容包括接口等。     

Supercritical Fluid Extraction (SFE) Optimization by Full-Factorial Design for the Determination of Irganox 1076, Irgafos 168, and Chimassorb 81 in Virgin and Recycled Polyolefins

The performance and feasibility of supercritical fluid extraction (SFE) applied to the extraction of some antioxidants (Irganox 1076, Irgafos 168) and one UV-stabilizer (Chimassorb 81) from both virgin and recycled low density polyethylene (LDPE), and virgin high density polyethylene (HDPE) are studied. Due to the high number of variables a full-factorial design has been applied to minimize the number of experiments required to reach the optimum extraction conditions. Further analysis has been carried out off-line by reversed-phase HPLC. Modification of the physical properties of the polymeric matrix and increased number of recycling cycles as well as the influence of physical properties on the efficiency of SFE are also discussed.     

Supercritical fluid extraction in herbal and natural product studies - a practical review

Due to increasingly stringent environmental regulations, supercritical fluid extraction (SFE) has gained wide acceptance in recent years as an alternative to conventional solvent extraction for separation of organic compounds in many analytical and industrial processes. In the past decade, SFE has been applied successfully to the extraction of a variety of organic compounds from herbs and other plants. This review article presents the practical aspects of SFE applications in sample preparation, selection of modifiers, collection methods, on-line coupling techniques, means for avoiding mechanical problems, and approaches to optimization of SFE conditions. SFE can also be used to clean up pesticides from herb medicines. SFE processes can be modeled to acquire useful information for better understanding of the extraction, mechanisms and optimization of the extraction procedures. With increasing public interest in natural products, SFE may become a standard extraction technique for studying herbal, food and agricultural samples.     

Direct solventless supercritical fluid extraction of chlorbiphenyls from aqueous solutions at 0.1 × 10–12 g/g level and whole extract analysis by GC/ECD

A method of PCB determination in water based on direct supercritical fluid extraction (SFE) and off-line solventless SFE/GC coupling has been developed. High SFE recovery of the targeted compounds from water and high efficiency of their solventless transfer into GC were achieved. The method can be used for fast screening of water samples for PCBs at ultratrace levels.