几种生物碱基的反相高效液相色谱分离及人尿中尿嘧啶和腺嘌呤的…

本文报道在ＳｐｈｅｒｉｓｏｒｂＣ１８柱上，以Ｈ３ＰＯ４－ＫＨ２ＰＯ４溶液作流动相（ｐＨ４．０），同时分离和测定胞嘧啶，尿嘧啶，腺嘌呤和黄嘌呤５种生物碱基，用于人尿分析，标准加入回收率在９２．５～１０５．５％之间。     

高效液相色谱法测定人血浆中甲磺酸培氟沙星浓度

建立了一种测定人血浆中甲磺酸培氟沙星的匠相液相色谱方法,用的是ＺｏｒｂａｘＯＤＳＣ＿（１８）柱和用三乙醇胺调节成ｐＨ为３．０的甲醇－０．０４ｍｏｌ／ＬＨ＿３ＰＯ＿４溶液（８０：２０,Ｖ／Ｖ）的流动相,检测在２７６ｎｍ处进行,流量为１ｍＬ／ｍｉｎ,线性范围是６．０１×１０￣（－８）～３．０１×１０￣（－５）ｍｏｌ／Ｌ（γ＝０．９９９８）,检测极限为６．０１×１０￣（－８）ｍｏｌ／Ｌ,平均回收率为９７．５７±３．０４％,日内与日间的ＣＶ分别为３．２９％和５．０８％。     

反相高效液相色谱法测定尿中吡啶醚和脱氧吡啶醚

尿中吡啶醚（ｐｙｒｉｄｉｎｏｌｉｎｅ,ＰＹＤ）和脱氧吡啶醚（ｄｅｏｘｙｐｙｒｉｄｉｎｏｌｉｎｅ,ＤＰＤ）是骨代谢特异的生化指标。应用高效液相色谱法（ＨＰＬＣ）建立了尿中ＰＹＤ和ＤＰＤ的测定方法。尿液用６ｍｏｌ／ＬＨＣｌ水解后,以纤维素ＣＦ１小柱提取,然后用ＨＰＬＣ测定;色谱系统为ＳｐｈｅｒｉｓｏｒｂＣ１８反相色谱柱,流动相组成为１５％甲醇添加０．１％七氟丁酸,流速为１．２ｍＬ／ｍｉｎ。系统的检测限：ＰＹＤ为１０ｎｍｏｌ／Ｌ,ＤＰＤ为７ｎｍｏｌ／Ｌ;回收率：ＰＹＤ为９１．５％,ＤＰＤ为１０６．１％;日内变异     

1─（2─吡啶偶氮）─2─萘酚─6─磺酸衍生化反相高效液相色谱法测定铁、钴、镍

本文研究了水溶性试剂１－（２－吡啶偶氮）－２－萘酚－６－磺酸（ＰＡＮ－Ｓ）与铁（Ⅱ）、钴（Ⅱ）和镍（Ⅱ）之螯合物的衍生和液相色谱分离条件。在Ｎｏｖａ－ＰａｋＴＭＣ１８柱上，用含１０ｍｍｏｌ／Ｌ的ｐＨ５．０的醋酸－醋酸钠缓冲溶液的甲醇－水溶液（５０：５０，Ｖ／Ｖ）作流动相，溴化四丁基铵（ＴＢＡ·Ｂｒ）作离子对试剂，流动相流速为１．０ｍＬ／ｍｉｎ，在５５０ｎｍ波长处进行光度检测。在Ⅱｍｉｎ内用高效液相色谱分离测定了Ｆｅ（Ⅱ）、Ｃｏ（Ⅱ）和Ｎｉ（Ⅱ）与ＰＡＮ—Ｓ的螯合物，提出了离子对反相高效液相色谱快速分离测定痕量铁、钴、镍的新方法。信噪比（ＳＮＲ）为２时，检测下限分别为０．０４３、０．００７和０．０１２ｍｇ／Ｌ。     

铁,钴,镍的反相高效液相色谱分离和测定

１引言建立了用反相高效液相色谱同时测定铁、钴、镍的分析方法并对Ｍｅｎ＋－二硫腙（ＤＺ）体系的色谱行为进行了探索。较之萃取进样更快速、简便。测定条件为：Ｓｈｉｍ－ＰａｃｋＣＬＣ－ＯＤＳ（φ６×１５０ｍｍ，５μｍ）；流动相：甲醇：水：三氯甲烷（含１％三乙胺）（８０：１０：１０）；流速１ｍＬ／ｍｉｎ；柱温３５℃；检测波长２５４ｎ。线性范围０．０１－２．０ｍｇ／Ｌ；相关系数ｒ＝０．９９９ｌ～０．９９９８；检测限为０．００２３～０．００５０ｍｇ／Ｌ；相对标准偏差为１．８％－２．７％；回收率为９６％－１０４…     

液相色谱法测定生物发酵液中水溶性维生素的研究

本文采用反相离子对色谱测定了生物发酵液中的七种水溶性维生素。提出了用自行装填的酸性氧化铝（０．１９～０．１５ｍｍ）前置柱，和５％乙酸洗脱样品的前处理方法；并就有关的色谱条件进行了选择。色谱柱为ＮｏｖａＰａｋＣ１８；流动相Ａ液为０．０５ｍｏｌ／Ｌ庚烷磺酸盐（ＰＩＣＢ７），冰乙酸调ｐＨ＝２．５；Ｂ液为甲醇＋三乙胺（１００＋０．５）；梯度洗脱；ＵＶ２５４ｎｍ、２９０ｎｍ、３６０ｎｍ同时测定。线性范围为０．１～１０μｇ，各种维生素的ＲＳＤ在１．２％～３．０％之间（ＶｉｔａｍｉｎＢ１２除外），回收率大于９０％。     

用反相高效液相色谱法分析测定Cd,Hg,Pb和Cu

用直接进样（Ｃ１８柱）反相高效液相色谱法研究了Ｍｅｎ＋－Ｄｚ（二硫腙）体系的色谱行为,建立了同时测定Ｃｄ,Ｈｇ,Ｐｂ和Ｃｕ的分析方法。方法的线性范围为０．０１～２．０ｍｇ／Ｌ,最低检出质量浓度为２．４～５．０μｇ／Ｌ,相对标准偏差为１．８％～９．７％,回收率为９４％～１０３％（Ｈｇ除外）。直接进样反相高效液相色谱法比萃取进样正相液相色谱法更快速,更简便,更容易操作,已用于人发测定。     

高效液相色谱法测定荧光增白剂OB

本文建立了高效液相色谱测定荧光增白剂ＯＢ，即２．５－双（５－叔丁基－２－苯并恶唑基）噻吩的方法。采用ＹＷＧ Ｃ１８色谱柱，四氢呋喃－水（６７：３３Ｖ／Ｖ）为流动相，流速１．０ｍＬ／ｍｉｎ，紫外检测波长３６０ｎｍ，柱温４０℃，分离时间少于１１ｍｉｎ。应用于工业产品的测定，结果满意。     

反相HPLC测定钒,铌,钽的2—（2—吡啶偶氮）—5—二乙氨基苯酚配合物

以２－（２－吡啶偶氮０－５－二乙氨基苯酚（ＰＡＤＡＰ）为柱前衍生试剂，在含０．１％酒石酸的１０ｍｍｏｌ／Ｌ（ｐＨ３．５）ＨＡｃ－ＮａＡｃ缓冲溶液的甲醇／水（５０∶５０，Ｖ／Ｖ）中（５８０ｎｍ检测），在Ｃ１８柱上于１１ｍｉｎ内实现了Ｖ、Ｎｂ、Ｔａ的同时分离及测定，检出限（Ｓ／Ｎ＝３）杰０．３４、０．２９、７．３０ｎｇ／ｍＬ．该法灵敏度高，用于矿样分析所得民推荐值相行，标准加入回收率为９９．０％～１０     

蜂蜜中四环素族抗生素残留量的薄层色谱测定法

残留在蜂蜜中的四环素族抗生素在经Ｓｅｐ－ＰａｋＣ１８小柱固相萃取处理后，用高效正相薄层色谱予以分离，喷雾显色后用紫外灯进行定性分析；使用双波长薄层扫描仪进行定量测定。在蜂蜜中的添加量为００５０×１０－３、０１０×１０－３及０２０×１０－３时，强力霉素（ＤＣ）、土霉素（ＯＴＣ）和四环素（ＴＣ）的回收率分别为９１６％～１００３％、８４５％～１０３１％和７７０％～１０３２％。该法的测定低限可达到１０－３μｇ。     

固相萃取-气相色谱/质谱法同时测定涂料中的8种有机锡

建立了一种固相萃取（SPE）前处理、气相色谱-质谱（GC-MS）法同时测定涂料中8种有机锡的方法。样品采用阳离子交换固相萃取小柱净化,最佳固相萃取条件为：固相萃取小柱分别用5mL甲醇、7mL洗脱液（氯化铵、甲醇、冰乙酸的混合溶液）预洗,10mL甲醇活化;将用甲醇稀释的涂料样品上样后,用5mL甲醇淋洗,抽干2min,7mL乙酸-氯化铵甲醇溶液（10：90,V／V）洗脱溶液洗脱。洗脱液用四乙基硼化钠溶液衍生后,气相色谱-质谱法进行定性定量分析。结果表明：以标准加入法计算回收率,在1.68％-16.84%添加范围内,平均回收率在85％-105％之间,相对标准偏差均小于12％。     

固相萃取-超高效液相色谱-串联质谱法测定蜂产品中10种头孢类药物

建立了蜂产品中10种头孢类药物（头孢喹肟、头孢噻肟、头孢洛宁、头孢哌酮、头孢匹林、头孢氨苄、头孢乙腈、头孢拉定、去乙酰基头孢匹林、头孢唑林）含量的液相色谱-串联质谱测定方法。蜂产品样品中头孢类药物用乙腈-水（80：20,v/v）溶液提取,离心,上清液经Oasis PRIME HLB固相萃取柱净化,氮吹后复溶,进行液相色谱-串联质谱分析。采用Acquity BEH C18色谱柱,以0.1%（v/v）甲酸水溶液-甲醇体系作为流动相进行梯度洗脱,ESI源正离子模式电离,多反应离子监测模式（MRM）检测,基质校准外标法定量。结果表明,10种头孢类药物在一定浓度范围内峰面积与质量浓度的相关系数（r²）大于0.999,线性关系良好;检出限为0.15~1.5 μg/kg,定量限为0.50~5.0 μg/kg;在阴性蜂产品样品中的加标回收率为75.0%~89.8%,相对标准偏差（RSD）为1.4%~4.6%（n=5）。该方法检测周期短,准确度和精密度高,能满足多种蜂产品样品中头孢类药物的检测需要。     

A rapid and reliable solid-phase extraction method for high-performance liquid chromatographic analysis of opium alkaloids from papaver plants

A rapid and reliable solid-phase extraction method for HPLC analysis of opium alkaloids from Papaver plants was established. Fifty mg of dried and powdered plant sample was extracted with 5 ml of 5% acetic acid for 30 min under sonication. After centrifugation, 3 ml of the supernatant was loaded on a reversed-phase cation-exchange solid-phase extraction cartridge. After seriate washings with 0.1 M hydrochloric acid and methanol, alkaloids were eluted with a mixture of 28% ammonia and methanol (1:19). The eluate was concentrated under nitrogen stream at 40 degrees C and the residue was dissolved in 50% aqueous methanol for high performance liquid chromatographic analysis. With this solid-phase extraction method, the recovery of morphine, codeine, oripavine, thebaine, papaverine, noscapine and sanguinarine was from 99.94 to 112.18% when the standard alkaloids were added to the plant samples. Opium alkaloids of a variety of genus Papaver plants cultivated in a field and phytotron were analyzed by this method.     

超高效液相色谱-串联质谱同时检测血液中29种农药

本文采用超高效液相色谱-串联质谱法(UPLC-MS/MS)和固相萃取法(SPE)建立了血液中29种农药同时筛查、定性、定量分析的方法,血液经4%磷酸水溶液稀释后,震荡10min,以8000r·min-1转速离心10min,取上清液过3mL甲醇和3mL水活化好的Oasis Prime HLB(3cc,60mg)固相萃取小柱,使用3mL5%甲醇水淋洗,3mL乙腈甲醇混合溶剂(90:10)洗脱,接收洗脱液后在40℃条件下氮吹仪吹干,使用0.5mL初始流动相复溶,震荡10s后,过0.22μm水膜,装液质小瓶后进样分析。采用ACQUITY UPLC HSS C18色谱柱(150 mm×2.1mm,1.8μm)分离,流动相为0.1%甲酸乙腈-水/甲酸/甲酸铵(5mmol,pH=3),梯度洗脱,电喷雾电离正离子模式(ESI+),多反应选择离子监测模式(MRM)检测。29种农药的检出限为0.1 ng·mL^-1~5 ng·mL^-1,定量限为0.5 ng·mL^-1~10 ng·mL^-1,回收率为62.4%~97.4%,基质效应为82.8%~109%,相对标准偏差小于10.3%,相关系数均大于0.99,线性关系良好范围为10 ng·mL^-1~1000ng·mL^-1。本文方法灵敏度高,可以对血液中29种农药成分进行筛查、定性、定量分析,能够满足实际血液样品中农药成分检测的需求。     

多壁纳米碳管固相萃取测定水中的有机氯农药

对于水样中的有机氯农药的净化方法主要是采用传统的液液分配的方法,缺点是溶剂使用量和前处理复杂。近年来固相萃取及固相微萃取等技术被应用到水样中的有机污染物的测定。如利用键合在硅胶上的非极性(C18,LC18等)或极性物质(LC-CN,LC-NH2)对水中有机物进行富集,用GDX或XAD自填的固相柱的报道也很多。纳米技术和纳米材料的发展为开发固相萃取材料带来新契机。纳米材料是指尺寸大小在从1～100m之间物质。与普通的块体材料相比,纳米材料具有较大的比表面,因而有可能具有较大吸附容量。纳米材料在环境有机污染物分离富集方面的应用研究才刚刚开始。本文主要就纳米碳管对水样中的有机氯农药进行研究,优化固相萃取条件。     

固相萃取-气相色谱/质谱联用测定环境水中噻唑硫磷农药残留

建立了对环境水中噻唑硫磷农药残留进行检测的离线固相萃取-气相色谱/质谱联用(SPE-GC/MS)的方法。固相萃取采用C18柱,用甲醇洗脱;GC/MS采用选择离子监测模式。该方法具有较高的灵敏度和选择性,对环境水中噻唑硫磷的最低检测质量浓度为56.4 ng/L(S/N=3);在0.282~141 μg/L时,响应值与样品浓度呈良好的线性关系;加样回收率大于85.5%,相对标准偏差（RSD）小于4.42%。方法操作简便、快速,可用于施用噻唑硫磷后环境水中痕量农药的监测。     

Comparison of C18 silica and multi‐walled carbon nanotubes as the adsorbents for the solid‐phase extraction of Chlorpyrifos and Phosalone in water samples using HPLC

A comparison between C₁₈ silica and multi‐walled carbon nanotubes (MWCNTs) in the extraction of Chlorpyrifos and Phosalone in environmental water samples was carried out using HPLC. Parameters affecting the extraction were type and volume of elution solvent, pH and flow rate of sample through the adsorbent. The optimum conditions obtained by C₁₈ cartridge for adsorption of these pesticides were 4 mL dichloromethane as elution solvent, sample pH of 5, flow rate of 1 mL/min, and those for MWCNT cartridge were 3 mL dichloromethane, pH of 5 and flow rate of 10 mL/min, respectively. Optimized mobile phase for separation and determination of these compounds by HPLC was methanol/water (80:20 v/v) with pH=5 (adjusted with phosphate buffer). Under optimal chromatographic and SPE conditions, LOD, linear range and precision (RSD n=8) were 3.03×10^?3, 0.01–5.00 μg/mL and 2.7% for Chlorpyrifos and 4.03×10^?4, 0.01–5.00 μg/mL and 2.3% for Phosalone, in C₁₈ cartridge, respectively. These values for MWCNT were 4.02×10^?6, 0.001–0.500 μg/mL and 1.8% for Chlorpyrifos and 1.02×10^?6, 0.001–0.500 μg/mL and 1.5% for Phosalone, respectively.     

Solid-phase extraction of soy isoflavones

An automated method using solid-phase extraction (SPE) for the concentration and clean-up of soy isoflavone extracts is proposed in this work. Using a standardized sample (0.1 g of a freeze dried soybean extract/25 mL of water); eight SPE cartridges with a wide range of sorbents (C18, divinylbenzene and modified divinylbenzene) from different suppliers were evaluated and compared. A large variation on SPE cartridges performance was observed, especially regarding retention and breakthrough volume of isoflavones during sample load and washing steps. The most effective cartridges were the divinylbenzene based cartridges, especially Strata X (from Phenomenex) and HLB oasis (from Waters). Using Strata X cartridges, several extraction parameters, such as sample loading flow (5-15 mL min(-1)), extracting solvent volume (2-6 mL of methanol), pH of the extracting solvent and the necessity of drying the sorbent before elution, were evaluated to provide a fast, specific, quantitative and reproducible SPE method. The optimized method consists of conditioning the cartridge with 10 mL of methanol and 10 mL of water (10 mL min(-1)), loading 25 mL of the standardized extract onto the cartridges (5 mL min(-1)), washing the cartridge with 10 mL of water (10 mL min(-1)) and finally eluting with 4 mL of methanol (10 mL min(-1)). Mean isoflavones recovery was 99.37% and mean intra- and inter-day reproducibility was higher than 98%. The developed sample clean-up/concentration (6.25:1) method takes less than 10 min and can be used in the analysis of isoflavones from soy extracts.     

Evaluation of solid‐phase extraction procedures for the quantitation of venlafaxine in human saliva by high‐performance liquid chromatography

In recent years, the use of human saliva for diagnostic purposes has evoked great interest. Thus, the aim of this study was to choose the optimal solid‐phase extraction cartridges and extraction solvents for the quantitation of venlafaxine in saliva. Blank saliva samples spiked with venlafaxine concentrations between 25 and 750 ng/mL were analyzed using five solid‐phase extraction columns (C18, C8, Strata‐X, Strata‐X‐C, and Strata‐X‐AW), washing solvents (deionized water, phosphate buffer at pH 5.5, and their mixtures with methanol), and elution solvents (methanol, acetonitrile, and their mixtures with 25% ammonia). A high‐performance liquid chromatography system was used to quantify venlafaxine in saliva. The results of this study revealed that nine of 25 procedures enabled quantitation of venlafaxine in the tested concentration range. The procedure that used a C18 cartridge, a mixture of methanol and deionized water as the washing solvent, and methanol as the elution solvent was the most effective and allowed quantitation of all venlafaxine concentrations with an acceptable recovery. In contrast, the Strata‐X‐C cartridge could not detect venlafaxine at the lowest concentration (25 ng/mL). The data acquired from the high‐performance liquid chromatography system were confirmed by a multivariate data analysis.     

Determination of chloramphenicol residues in bee pollen by liquid chromatography/tandem mass spectrometry

A novel liquid chromatographic/tandem mass spectrometric (LC/MS/MS) method was developed for the trace residue determination of chloramphenicol (CAP) in bee pollen. CAP was extracted from bee pollen with a mixture of methanol and 1% metaphosphoric acid solution, followed by a 2-stage solid-phase extraction enrichment and cleanup. The first stage involved a polymeric cartridge, and the second stage involved an alumina neutral cartridge. The LC separation was performed on a C18 column with 10 mM ammonium formate-acetonitrile (7 + 3) as the mobile phase and MS detection with negative-ion electrospray ionization. CAP-d5 was used as the internal standard. The method was validated according to Commission Decision 2002/657/EC. The calibration curves were linear between 0.1 and 5.0 ng/mL, and overall recoveries ranged from 98 to 113%. Decision limits (CCalpha) ranged from 0.05 to 0.07 microg/kg, and detection capabilities (CCbeta) ranged from 0.08 to 0.12 microg/kg. The developed method was applied to 11 samples.