超声萃取/液相色谱-串联质谱法测定染整助剂中的二硬脂基二甲基氯化铵

建立了超声辅助萃取/液相色谱-串联质谱( LC - MS/MS)测定染整助剂中二硬脂基二甲基氯化铵(DSDMAC)的方法.将样品以甲醇为萃取溶剂进行超声萃取,萃取液经过滤后采用LC-MS/MS测定.采用电喷雾离子源,定性离子对为m/z 550.5/298.3、522.5/298.3、522.5/270.3、494.5/...     

硫化锌粉体中游离硫含量测试方法研究

介绍了关于硫化锌粉体中游离硫含量测定的样品处理和测试方法.以苯为萃取剂,用超声振荡方式进行萃取,并用单质硫的苯溶液标样代替有机硫标样标定库仑仪的回收率.回收率为112%～115%,测定结果的相对标准偏差为0.6%～2.4%.     

食品纸包装材料中指示性多氯联苯的固相萃取/气相色谱-质谱联用法测定

建立了一种简单、快速测定食品纸包装材料中指示性多氯联苯的分析方法.采用溶剂超声萃取样品,通过C18固相萃取柱、浓硫酸净化后,用气相色谱-质谱联用仪(GC-MS)进行测定.并对不同的萃取溶剂和萃取方法进行了系统地比较,优化了实验条件,方法的回收率为88%～102%,相对标准偏差为3%～7%,定量下限为1.0 μg/kg.     

气相色谱-质谱法测定热塑性弹性体中的多环芳烃

建立了一种简单、准确的测定热塑性弹性体中16种多环芳烃(PAHs)的气相色谱-质谱(GC-MS)方法。考察了样品制备、萃取溶剂、萃取方法、时间以及温度对厂家制备的阳性热塑性弹性体样品中PAHs提取效率的影响,确定了萃取条件和方法。样品经甲苯超声萃取、浓缩后用环己烷溶解、二甲亚砜液液萃取净化后采用GC-MS进行分析,内标法定量。通过对不同材质阳性热塑性弹性体样品的加标回收、精密度试验等对建立的方法进行评价,16种PAHs的平均回收率为70%～117%,精密度为0.2%～10.8%。该方法适合于热塑性弹性体中PAHs的测定。     

气相色谱法测定树脂工艺品中的半挥发性有机物残留

建立了树脂工艺品中半挥发性有机物(SVOCs)的超声萃取–气相色谱检测方法。对超声萃取条件进行了研究,优化了气相色谱参数。结果表明,样品用三氯甲烷在60℃下超声萃取40 min,选择HP–5色谱柱时,气相色谱(FID)测定半挥发物总量时可获得良好的灵敏度和准确的定量结果。方法的相对标准偏差小于5%(n=6),检测限为2 mg/kg。4个含量水平样品的6个实验室3次平行测定结果表明,实验室内测定结果的相对标准偏差为1.61%~2.94%,实验室间测定结果的相对标准偏差为5.96%~8.35%。     

口香糖中人参总皂甙样品前处理方法比较研究

用乙醚分散口香糖胶基,温水超声提取,水饱和正丁醇萃取,可见分光光度法对样品进行定量测定。与人参皂甙测定的行业标准方法相比,本方法样品前处理方法更有效,样品测定结果线性好(r=0.9993),平均回收率为99.2%,精密度实验RSD为1.7%(n=6)。本方法可以作为口香糖中人参总皂甙分析测定的简便、快速方法。     

固相萃取高效液相色谱法测定冬虫夏草中甘露醇

研究了用固相萃取预分离高效液相色谱法测定冬虫夏草中甘露醇的方法.冬虫夏草样品用水超声振荡提取后用Waters Sep-Pak-C18固相萃取小柱预分离,以Waters Sugar-Pak-1钙型阳离子交换柱为固定相,0.05g@L-1EDTA钙钠溶液为流动相,示差折光仪为检测器测定冬虫夏草样品中甘露醇含量.方法检出限为2.5μg@ml-1,RSD在0.86%～1.23%之间,回收率在97%～102%之间.方法用于冬虫夏草样品中甘露醇的测定,结果满意.     

固相膜萃取-超声解吸-气相色谱-质谱法分析水中酞酸酯类化合物

酞酸酯(PAEs)是一种常用的增塑剂,由于其广泛应用已经对环境造成了污染.本研究建立了固相膜萃取-超声解吸-气相色谱-质谱分析水中酞酸酯类化合物的方法.对萃取条件、解吸条件进行了优化,确定了最佳的实验条件.在水浴温度40℃,超声功率50%的条件下超声7 min,测定水中PAEs的检出限(S/N>3)在0.05 ~0.26 μg/L之间;对不同基质空白样品进行加标回收实验,回收率在76.2%~112.3%之间,相对标准偏差小于10%.     

GC-MS法测定纺织品中16种邻苯二甲酸酯含量

采用超声萃取方法提取样品,建立了纺织品中16种邻苯二甲酸酯增塑剂含量测定的气相色谱-质谱（GC-MS）检测方法。以甲醇为萃取剂超声波辅助萃取,考察了超声萃取的温度和时间。在选定试验的条件下,当添加邻苯二甲酸酯类浓度为2～40mg／L时,该方法的加标回收率为84．7％-106．2％,测定结果的相对标准偏差（RSD）在1．8％～7．4％之间（n=7）.     

滤膜吸附结合超声辅助分散液液微萃取/高效液相色谱法测定空气中溴氰菊酯残留

建立了滤膜吸附结合超声辅助分散液液微萃取与高效液相色谱(HPLC)联用测定空气中溴氰菊酯残留的方法。空气样品用甲醇-水(1∶4)混合溶液提取,加入三氯甲烷进行微萃取,超声,离心,得到沉积相,进行HPLC分析。溴氰菊酯在5~1 000μg/L范围内线性关系良好,相关系数(r)为0.999 8,富集倍数达520倍。当空气样品的加标浓度为10,50,100μg/L时,加标回收率为78.6%~106.7%,相对标准偏差(RSD)为2.2%~4.3%。空气样品中溴氰菊酯的检出限为1μg/L,最低检出浓度为0.04μg/m~3。该方法具有简便快捷、准确灵敏、萃取效率高、有机溶剂消耗少等优点,可用于空气中溴氰菊酯残留的测定。     

Determination of total flavonoids in Scutellaria barbata D. Don by dynamic ultrasonic extraction coupled with on-line spectrophotometry

A dynamic ultrasonic extraction (DUE) coupled with on-line detection by spectrophotometry is proposed for the determination of total flavonoids (calculated against scutellarin) in Scutellaria barbata D. Don. The extraction was performed in a common self-made extraction vessel put in an ultrasonic bath and a peristaltic pump was used to deliver the extraction solvent. Several experimental parameters of DUE, including flow rate and concentration of extraction solvent, ultrasonic power and sample amount, were optimized. In this work an on-line method was provided with the advantages of minimum sample amount (5 mg), on-line monitoring the extraction process and time saving (12.5 min). Compared with off-line method, the proposed method would be more convenient for obtaining continuous measurements and rapid optimization of the extraction process.     

Direct ultrasonic agitation for rapid extraction of organic matter from airborne particulate

Direct ultrasonic extraction (DUE) is proposed as simple and rapid sample pretreatment method. This new approach is applied to the extraction of particulate organic matter (POM) from airborne particulate by using dichloromethane (DCM) or DCM/methanol (90/10, v/v) as extractant. The analytical determination was carried out by weighing the extractable POM on an electrobalance. Total recovery for POM could be obtained when the sample was extracted three times with 25-50 mL extractant each for about 5 min at 50 W ultrasonic power. In comparison with conventional Soxhlet extraction, less extraction time (total 15 min only) and solvent consumption (100 mL) were required by DUE. The efficiency of the DUE was similar or even higher than the routine Soxhlet method. Additionally, the new extractor is very simple and easy to use and can accelerate the extraction procedures of organic components from various solid samples.     

Direct ultrasonic agitation for rapid extraction of organic matter from airborne particulate

Direct ultrasonic extraction (DUE) is proposed as simple and rapid sample pretreatment method. This new approach is applied to the extraction of particulate organic matter (POM) from airborne particulate by using dichloromethane (DCM) or DCM/methanol (90/10, v/v) as extractant. The analytical determination was carried out by weighing the extractable POM on an electrobalance. Total recovery for POM could be obtained when the sample was extracted three times with 25–50 mL extractant each for about 5 min at 50 W ultrasonic power. In comparison with conventional Soxhlet extraction, less extraction time (total 15 min only) and solvent consumption(100 mL) were required by DUE. The efficiency of the DUE was similar or even higher than the routine Soxhlet method. Additionally, the new extractor is very simple and easy to use and can accelerate the extraction procedures of organic components from various solid samples.     

FI溶剂萃取与ICP-AES联机的研究水样中微量铜的测定

本文建立了用FI-溶剂萃取-ICP-AES测定水样中微量铜的分析方法。选择了ICP-AES、超声雾化发生器及FIA的最佳工作条件。研究了溶液pH对用打萨腙-四氯化碳体系萃取铜的影响;有机相流速与水相流速之比例;萃取盘管长度等因素对萃取过程及等离子体放电的影响。分析了自来水样品及美国标准局标准水样中铜含量。统计了分析方法的精密度、检出限与实验条件下的富集倍数。     

Ultrasonic nebulization extraction coupled with headspace hollow fiber microextraction of pesticides from root of Panax ginseng C.A. Mey

The ultrasonic nebulization extraction coupled with headspace hollow fiber microextraction (UNE-HS-HFME) was applied for the extraction of pesticides from root of Panax ginseng C.A. Mey. Experimental parameters, which affect the performances of ultrasonic nebulization extraction coupled with headspace hollow fiber microextraction, such as the kind of acceptor solvent in the pore of the fiber wall, the sample amount, extraction time, salt concentration in extraction solvent, pH of the acceptor solution, the elution time, and times were studied and optimized. The analytes were determined by high-performance liquid chromatography. The detection limits for simeton, monolinuron, chlortoluron, karmex, and prebane are 20.9, 18.4, 18.2, 12.4, and 22.2 μg/kg, respectively. Besides volatile and semi-volatile compounds, the non-volatile compounds also can be determined by the proposed method. The extraction and enrichment process can be performed simultaneously.     

On-line continuous flow ultrasonic extraction coupled with high performance liquid chromatographic separation for determination of the flavonoids from root of Scutellaria baicalensis Georgi

An on-line method, based on coupling dynamic ultrasonic extraction (DUE), continuously sampling the suspension of sample and solvent, high performance liquid chromatographic separation with diode array detection, has been developed for the determination of the flavonoids, including baicalin, baicalein and wogonin, from the root of Scutellaria baicalensis Georgi. Variables influencing the DUE were evaluated by orthogonal test. The extraction yields of baicalin, baicalein and wogonin in the roots of S. baicalensis Georgi obtained from five different cultivated areas are 73.8–131.5 μg mg⁻¹ (RSD ≤ 6.24%), 6.8–15.9 μg mg⁻¹ (RSD ≤ 5.36%) and 4.4–14.3 μg mg⁻¹ (RSD ≤ 5.30%), respectively. The limits of detection for baicalin, baicalein and wogonin are 0.30, 0.37 and 0.41 μg mL⁻¹, respectively. Linearity is from 0.55 to 109 μg mL⁻¹ for baicalin, from 0.51 to 105 μg mL⁻¹ for baicalein and from 0.53 to 102 μg mL⁻¹ for wogonin. Compared with off-line continuous flow-DUE, the proposed method would be more convenient for the determination of the analytes and the rapid optimization of the extraction process. The extraction yields of flavonoids obtained by the proposed method are comparable with those obtained by dynamic microwave assisted extraction, static ultrasonic extraction and reflux extraction. The result indicated that the proposed method is suitable to determine the active components in Chinese herbal medicine.     

On-line coupling of dynamic microwave-assisted extraction with high-performance liquid chromatography for determination of andrographolide and dehydroandrographolide in Andrographis paniculata Nees

A novel technique based on dynamic microwave-assisted extraction (DMAE) coupled on-line with high-performance liquid chromatography (HPLC) through a flow injection interface has been developed for determination of andrographolide and dehydroandrographolide in Andrographis paniculata Nees. A TM(010) microwave resonance cavity built in the laboratory was applied to concentrating the microwave energy. An extraction vessel was placed in microwave irradiation zone. The extraction was performed in a recirculating system. When a number of extraction cycles were completed, the fractional extract (20muL) was driven to the analytical column by 65% aqueous methanol and was measured by diode array detector (DAD) at 225nm. The optimized extraction conditions are follows: extraction solvent 60% aqueous methanol; microwave forward power 80W; extraction time 6min; extraction solvent flow-rate 1.0mLmin(-1). The detection and quantification limits obtained are 0.5 and 1.7microgmL(-1) for andrographolide and 0.6 and 1.9microgmL(-1) for dehydroandrographolide, respectively. The within-day and between-day precision (RSD) are 2.1% and 3.7% for andrographolide and 1.7% and 4.1% for dehydroandrographolide, respectively. Mean recoveries for andrographolide and dehydroandrographolide are 97.7% and 98.7%, respectively. Compared with ultrasonic extraction used in the Chinese pharmacopoeia, the proposed method was demonstrated to obtain higher extraction yield in a shorter time. In addition, only small quantities of solvent (5mL) and sample (10mg) were required.     

On-line sample treatment and FT-IR determination of doxylamine succinate in pharmaceuticals

A low solvent consumption method for Fourier transform infrared spectroscopy (FT-IR) determination of doxylamine succinate in pharmaceuticals has been developed. The analyte was continuous and selectively extracted with a 13% (v/v) ethanol:chloroform solvent mixture, recirculating the solvent through the sample and monitoring the process by FT-IR. Doxylamine succinate was determined by on-line standard addition measuring the peak area in the regions 1730–1710 and 1485–1462 cm⁻¹ corrected with a two-point baseline established between 2000 and 1800 cm⁻¹. This new method implies low volumes of chloroformic solvent mixture, only 2.6 mL per sample, in front of classical batch FT-IR methods, improving analytical efficiency and reducing waste generation. The on-line extraction and standard addition determination of doxylamine succinate allowed a throughput of 10 h⁻¹.     

Development of liquid phase microextraction based on manual shaking and ultrasound-assisted emulsification method for analysis of organochlorine pesticides in aqueous samples

A novel method using sample preparation method, "ultrasound-assisted emulsification microextraction" (USAEME) with manual shaking, coupled with gas chromatography using and an electron capture detector (GC-ECD) was developed for the analysis of organochlorine pesticides (OCPs) in aqueous samples. The apparatus is simple and easy to operate. After manual shaking for 10s, ultrasound was used to accelerate emulsification of the organic solvent (1-decanol) in aqueous solution. Only 10 μL of the low-toxicity extraction solvent is used in this method; no dispersive solvent is required and the total extraction time is ～4 min. Manual shaking before ultrasound-assisted emulsification enhances the extraction efficiency by >100%. The effects of horizontal and vertical orientation as well as the location of the sample within the ultrasonic bath were studied. After centrifugation, we used an improved solvent collection system (ISCS) to reduce the amount of extraction solvent required. A 1 μL sample of the extract was injected into the GC column. Under optimum conditions, the linear range of the method is 5-2500 ngL(-1) for most of the OCPs, and the limit of detection of the method ranged from 0.6 to 2.9 ngL(-1).The relative recoveries ranged from 75 to 107% for sea water and from 70 to 99% for field fresh water. The method, which provides good enrichment factors, low LODs and minimization of the consumption of organic solvent, provides a rapid, simple and environment-friendly procedure for determining OCPs in aqueous samples.     

Determination of trace benzene derivatives in aqueous samples by ultrasonic enhanced hollow fiber liquid-phase microextraction prior to gas chromatography

A new method was developed for the determination of trace compounds in water samples using ultrasonic-enhanced hollow fiber liquid-phase microextraction (U-HF-LPME). The ultrasonic radiation, which produces mechanical vibration and ultrasonic cavitation, could be used for accelerating the diffusion mass transfer process. Thus, ultrasonic was introduced into the HF-LPME procedure to enhance the mass-transfer rate during the aqueous and extraction solvent phases. Experimental parameters such as the extraction solvent, the extraction time, the ultrasonic frequency and power, the extractant volume, and ionic strength of the sample were assessed and optimized. Under optimal conditions, HF-LPME was achieved within 10 min. The high enrichment factor in the range of 120-666 and a good relative recovery in the range of 97-103% were evaluated with the relative standard deviations (RSDs, n = 5) of 0.3-7.0%. The limit of detection was in the range of 0.8-3.0 μg/L. The method was applied to the analysis of groundwater, lake water, and seawater. The results showed that the method can determine trace benzene derivatives in real samples with RSD values of 1.1-4.2%. The results demonstrated that U-HF- LPME is a rapid, accurate, and effective sample preparation method, and could be successfully applied for the determination of trace compounds in analytical chemistry.