一种固液,液液连续萃取新装置

根据联通管原理,作者设计了一套固液,液液连续萃取装置(图1)。可封闭,可开放;可热萃,亦可冷萃,还可用磁力搅拌器搅拌。装置说明:图1的装置由两个三颈瓶A、B组成。“1”、“2”为温度计,若不需控温可改为磨口塞。“3”为冷凝管。“4”为带三通活塞的联通管。在固液萃取及萃取剂比重大的液液     

分析化学中的溶剂萃取技术

综述了近年来溶剂萃取在分析化学中应用的发展趋势。对溶剂萃取所发展的超临界流体萃取、固相萃取、固相微萃取及膜萃取方面作了重点叙述。引用文献35篇。     

二烷氧基膦酰乙酸烷基酯对镧系元素的萃取性能

报道了6个具有不同烷基结构的新型中性双配位有机磷萃取剂——二烷氧基膦酰乙酸酯(R_1O)_2PO-CH_2-CO-OR_2对镧系元素的萃取性能和规律。该类萃取剂中二个配位基团P=O和C=O附近的酯烷基R_1和R_2的结构变化明显地影响其对镧系元素的萃取能力,分配系数随着镧系元素原子序数的增大而呈双峰效应,萃取机理与一般中性溶剂化络合萃取相似。萃取配台物中镧系元素与配体的摩尔比为1:3,并用元素分析、分子量测定和红外光谱对二丁氧基膦酰乙酸异丙酯与硝酸镧配合物进行了研究。     

褐煤超临界流体抽提产物中脂肪烃组成结构的特征

用硅胶-氧化铝柱色谱预分离和色谱-质谱分析研究了两种褐煤超临界流体抽提物中脂肪烃馏分组成结构特征。结果表明,除主要成份正构烷烃(C_(13)～C_(33))外,尚有少量的类异戊二烯烃(姥鲛烷、植烷等)和萜烷。其中萜烷以五环三萜为主(C_(27)、C_(29)～C_(32)藿烷类化合物),并有一定量的C_(27)、C_(29)和C_(30)藿烯,倍半萜和三环二萜烷含量很少。未检出甾烷。此外,还检出一完整系列的烯烃。试验结果表明,超临界流体抽提条件对褐煤抽出物各组分、含量及其分布有一定的影响。     

CuSO4—氨化P507—n—C6H14体系平衡常数的计算

用热力学方法研究了酸性磷取剂与金属体系间的平衡计算模型，萃取体系的水相采用Ｐｉｔｚｅｒ半经验公式求算γＣｕ＾２＋，有机相用热力学关系求出了水，正己烷和萃取剂的活度系数，实验结果用Ｓｃｈａｔｃｈａｒｄ－Ｈｉｌｄｅｂｒａｎｄ模型关系，并经回归处理，得到了萃取反应热力学平衡常数及萃合物的活度系数。     

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。     

东北泥炭亚临界—超临界萃取研究

在半连续装置上进行了中国东北几种泥炭非等温亚临界-超临界萃取研究。以甲苯作溶剂时最佳条件是:压力10MPa,温度330—350℃;以甲醇、乙醇作溶剂时最佳条件是:压力10MPa,温度300—320℃。萃取结果表明,生成萃取物的温度范围宽(180—420℃),主要集中在250—320℃温度区。选用灰分低、(H+N-O)/C原子比高的泥炭对萃取有利。动力学处理表明,主要萃取过程可用三级动力学方程描述,表观活化能为50—185KJ/mol。     

双（十二烷基亚磺酰）乙烷溶剂萃取钯及其机理的研究

本文研究用双（十二烷基亚磺酰）乙烷萃取钯的性能，在ＫＩ存在下从７ｍｏｌ／Ｌ盐酸介质中用含有ＢＤＳＥ的氯仿能定量萃取钯，有机的钯可被硫脲或氨溶液反萃继之用ＴＭＫ－ＴｒｉｔｏｎＸ－１００光度法测定，研究了萃取的最佳条件及干扰情况，斜率法测得萃合物组成为Ｐｄ：Ｉ：ＢＤＳＥ＝１：２：１，红外光谱证实萃合物中ＢＤＳＥ的二个亚砜以硫原子与钯配位，萃合物为异位体络合物，提出了选择性萃取分离钯的新方法。     

样品制备与处理的进展——无溶剂萃取技术

本文讨论了现代分析化学的重要领域之一, 样品制备及前处理技术的进展--无溶剂萃取技术。包括气相萃取、超临界流体萃取、膜萃取、固相萃取、固相微萃取等方法。简述了这些方法的原理及其应用, 探讨了样品制备与前处理技术的发展动向。     

固相微萃取萃取头制备技术及试验方法的进展

在阐述固相微萃取的平衡理论及非平衡理论基础上,重点探讨了萃取头的制备技术和相关试验方法的进展。除了介绍商品化通用萃取头的制备技术外,还论述了溶胶-凝胶法、电沉积法、碳素基体吸附法、高温环氧树脂固定法等新的制备技术;探讨了固相微萃取试验方法中萃取模式和萃取头的选择、萃取条件优化以及方法的灵敏度、精度、自动化等的评价;进一步总结了固相微萃取的应用现状,对固相微萃取的发展方向作了展望。     

新型无溶剂样品制备方法—固相微萃取法

固相微萃取法（SPME）是在固相萃取（SPE）的基础上结合顶空分析（Headspace)建立起来的一种新型样品制备方法,具有简便,经济、不使用溶剂等优点,并且能做到提取、净化、浓缩和仪器分析同步完成,文中对固相微萃取的装置,原理、萃取条件等、特点,应用及SPME法今后可能发展的方向作以介绍和进行初步探讨。     

Solid-phase microextraction: a promising technique for sample preparation in environmental analysis

Solid-phase microextraction (SPME) is a simple and effective adsorption and desorption technique, which eliminates the need for solvents or complicated apparatus, for concentrating volatile or nonvolatile compounds in liquid samples or headspace. SPME is compatible with analyte separation and detection by gas chromatography and high-performance liquid chromatography, and provides linear results for wide concentrations of analytes. By controlling the polarity and thickness of the coating on the fibre, maintaining consistent sampling time, and adjusting other extraction parameters, an analyst can ensure highly consistent, quantifiable results for low concentration analytes. To date, about 400 articles on SPME have been published in different fields, including environment (water, soil, air), food, natural products, pharmaceuticals, biology, toxicology, forensics and theory. As the scope of SPME grew, new improvements were made with the appearance of new coatings that allowed an increase in the specificity of this extraction technique. The key part of the SPME fibre is of course the fibre coating. At the moment, 27 variations of fibre coating and size are available. Among the newest are a fibre assembly with a dual coating of divinylbenzene and Carboxen suspended in poly(dimethylsiloxane), and a series of 23 gauge fibres intended for specific septumless injection system. The growth of SPME is also reflected in the expanding number of the accessories that make the technology even easier to use Also available is a portable field sampler which is a self-contained unit that stores the SPME fibre after sampling and during the shipment to the laboratory. Several scientific publications show the results obtained in inter-laboratory validation studies in which SPME was applied to determine the presence of different organic compounds at ppt levels, which demonstrates the reliability of this extraction technique for quantitative analysis.     

Solid-phase microextraction for herbicide determination in environmental samples

Liquid-liquid extraction or solid-phase extraction followed by gas chromatography (GC) or high-performance liquid chromatography are traditional herbicide residue determination methods for environmental samples. Solid-phase microextraction (SPME) is a solventless, fast, and sensitive alternative herbicide residue extraction method that can be applied to numerous environmental matrices. The objective of this paper was to review SPME literature regarding extraction theory, extraction modes, fiber types, and method optimization in conjunction with present and future SPME applications for herbicide determination in environmental samples.     

Headspace solid-phase microextraction procedures for gas chromatographic analysis of biological fluids and materials

Solid-phase microextraction (SPME) is a new solventless sample preparation technique that is finding wide usage. This review provides updated information on headspace SPME with gas chromatographic separation for the extraction and measurement of volatile and semivolatile analytes in biological fluids and materials. Firstly the background to the technique is given in terms of apparatus, fibres used, extraction conditions and derivatisation procedures. Then the different matrices, urine, blood, faeces, breast milk, hair, breath and saliva are considered separately. For each, methods appropriate for the analysis of drugs and metabolites, solvents and chemicals, anaesthetics, pesticides, organometallics and endogenous compounds are reviewed and the main experimental conditions outlined with specific examples. Then finally, the future potential of SPME for the analysis of biological samples in terms of the development of new devices and fibre chemistries and its coupling with high-performance liquid chromatography is discussed.     

Rapid analysis of environmental samples using solid-phase microextraction (SPME) and narrow bore capillary columns

The application of SPME, a solventless extraction procedure, is demonstrated for two environmental applications. Extraction of VOCs by SPME is coupled with analysis on short narrow bore capillary gas chromatography columns. The technique is shown both as a fast screening tool and as part of an analytical procedure when combined with a mass spectrometer. Data show the linear range of the procedure. The extraction of chlorinated pesticides from hazardous wastewater and drinking water by SPME is also described in this paper. SPME is compared to traditional extraction procedures with respect to cost, time, ease of use, solvent usage, and sample usage.     

SPME – Quo vadis?

Solid phase microextraction (SPME) has experienced rapid development and growth in number of application areas since its inception over 20 years ago. It has had a major impact on sampling and sample preparation practices in chemical analysis, bioanalysis, food and environmental sciences. A significant impact is expected in clinical analysis as well as pharmaceutical and medical sciences in the near future. In this review, recent developments of SPME and related technologies are discussed including an in-vial standard gas system for calibration of SPME in high throughput mode; a thin film geometry with high extraction efficiency SPME for gas chromatography (GC) and liquid chromatography (LC) analyses; and couplings of SPME with portable instruments permitting on-site measurements. Also, the latest advances in the preparation of sorbents applicable for direct extraction from complex biological matrices as well as applications of these extraction phases in food analysis and biomedical studies such as therapeutic drug monitoring and pharmacokinetics are described. Finally, recent trends in metabolomics analysis and examples of clinical monitoring of biomarkers with SPME are reviewed.     

Solid-phase microextraction versus single-drop microextraction for the analysis of nitroaromatic explosives in water samples.

This paper compares solid-phase microextraction (SPME) with a recently developed extraction method called single-drop microextraction (SDME) for the analysis of nitroaromatic explosives in water samples. The two techniques are examined in terms of procedure, chromatographic analysis and method performance. All practical considerations for both techniques are also reviewed. SPME requires dedicated apparatus and is relatively expensive, as the fiber's lifetime is limited. However, it has the advantages over SDME that it can be easily used for headspace analysis and has lower detection limits for all the target analytes. SDME requires more elaborate manual operations, thus affecting linearity and precision.     

Fast determination of phenols in contaminated soils

An extraction method for the determination of phenols in contaminated soils, based on the application of solid-phase microextraction (SPME) coupled with GC-flame ionization detection analysis, was developed and tested. This method was developed using a natural soil spiked with phenol to a concentration level typical of an acute contamination event that can occur in an industrial site. The effects of the extraction parameters (pH, extraction time and salt concentration) on the extraction efficiency were studied and the method was then applied to determine the pollutant concentration at the beginning and during the biological treatment of a soil, contaminated with phenol and 3-chlorophenol, respectively. The SPME results were validated by comparison with those obtained with an US Environmental Protection Agency certified extraction method. The SPME method was also successfully applied to the determination of the adsorption behavior of 3-chlorophenol on a natural clay soil and was shown to be suitable for different matrices and phenolic compounds. Application of SPME technique results in a sharp reduction of the extraction times with negligible solvent consumption.     

Bio-compatible in-tube solid-phase microextraction capillary for the direct extraction and high-performance liquid chromatographic determination of drugs in human serum

A restricted access material (RAM), alkyl-diol-silica (ADS), was used to prepare a highly bio-compatible solid-phase microextraction (SPME) capillary for the automated and direct in-tube extraction of several benzodiazepines from human serum. The bifunctionality of the ADS extraction phase prevented fouling of the capillary by protein adsorption while simultaneously trapping the analytes in the hydrophobic porous interior. This the first report of a restricted access material utilized as an extraction phase for in-tube SPME. The approach simplified the required apparatus in comparison to existing RAM column switching procedures, and more importantly eliminated the excessive use of extraction solvents. The biocompatibility of the ADS material also overcame the existing problems with in-tube SPME that requires an ultrafiltration or other deproteinization step prior to handling biological samples, therefore further minimizing the sample preparation requirements. The calculated oxazepam, temazepam, nordazepam and diazepam detection limits were 26, 29, 22 and 24 ng/ml in serum, respectively. The method was linear over the range of 50-50 000 ng/ml with an average linear coefficient (R2) value of 0.9998. The injection repeatability and intra-assay precision of the method were evaluated with five injections of a 10-microg/ml serum sample (spiked with all compounds), resulting in an average RSD<7%. The ADS extraction column was robust, providing many direct injections of biological fluids for the extraction and subsequent determination of benzodiazepines.