反胶束萃取-高效液相色谱法测定磺酸型偶氮染料

建立了水中磺酸偶氮染料甲基橙（MO）、刚果红（CR）和酸性铬兰K（ACBK）的反胶束萃取-离子对高效液相色谱定量检测的方法。采用Hypersil C18柱（250×4．6mm,5μm）,流动相为V（甲醇）／V（水）=63：37（含10mmol／L的KH2PO4、4mmol／L的四丁基溴化铵,KOH调pH=7．0）,流速为0.8mL／min,MO、CR和ACBK检测波长分别为449nm、505nm和526nm。结果表明,染料的回收率为92．9％～102．1％,相对标准偏差为0．9％～2．3％,水中MO、CR和ACBK的检出限分别为0．6μg／L、1．2μg／L和1．3μg／L。     

ASE-HPLC检测某型号球形发射药中的叠氮硝胺、硝化甘油、Ⅱ号中定剂含量的研究

采用快速溶剂萃取（ASE）技术和高效液相色谱法测定某球形药中叠氮硝胺（DIANP）、硝化甘油（NG）和Ⅱ号中定剂（C2）的含量．ASE提取条件：二氯甲烷做萃取溶剂,萃取温度100℃,静态萃取10min,萃取2次．HPLC测定条件：YWGC18柱（150×4．6mm,10μm）,以甲醇和水作为流动相,梯度洗脱,流速1 mL／min,检测波长210nm．测定结果表明DIANP、NG、C2平均回收率分别为99．6％、100．3％、99．4％,RSD分别为0．7％、0．8％、0．9％（n=5）,检出限分别为2.1、1.5和0．2mg／L,线性范围分别为0．02～0．98g／L,0．03～1．38g／L,0．002～0．124g／L．用此方法共检测某批球形发射药样品5份,检测结果与滴析-HPLC法检测结果相当．     

铅形态的高效液相色谱-电感耦合等离子体质谱分析

用50mm的反相高效液相色谱短柱在V甲醇/VH2O=55／45,其中水相为0．1mol／L乙酸0．1mol／L乙酸铵的缓冲溶液（pH=4．70）,流速0．6mL／min条件下,约10min内实现了无机铅离子（Pb^2＋）、氯化三甲基铅（TML）、氯化三乙基铅（TEL）和氯化三苯基铅（TPhL）的高效液相色谱．电感耦合等离子体质谱（HPLC-ICP-MS）联用分析。4种铅形态在去离子水和自来水中的加标回收率分别为93．8％-115．6％和89．3％-137．8％;峰强度和保留时间的RSD分别为7．4％-14．3％和0．5％-1．3％;仪器检出限及方法检出限分别为0．27-3．07μg/L和1．20-2．33μg／L。     

反相高效液相色谱法测定人血浆中利培酮及其代谢物的质量浓度

建立了测定人血浆中利培酮及其活性代谢物9-羟利培酮质量浓度的反相高效液相色谱方法。用Zor－baxODSC18色谱柱,以V（甲醇）：V（水）：V（1mol／L醋酸铵）：V（3mol／L氨水）＝300：50：3：1为流动相,检测波长为280nm,流速为0．8mL／min。利培酮的线性范围为2～600μg／L（r＝0．996）,回收率为（98．2±3．5）％,日内与日间的标准偏差分别为4．12％和4．83％;9-羟利培酮的线性范围为2～800μg／L（r＝0．998）,回收率为（97．8±3．8）％,日内与日间的标准偏差分别为4．28％和4．81％。     

离子色谱法测定水中的高氯酸盐

采用离子色谱法测定了饮用水中痕量的高氯酸盐,以30mmol／LNaOH为淋洗液,1mL／min流量,1000μL进样,在25min内可完成测定高氯酸盐;利用加热浓缩的方法对水样进行前处理,浓缩10倍后进样。结果表明,该法回收率为87．9％,检测限为0．10μg/L,具有实际应用价值。     

HPLC-ICP-MS或HPLC-FAAS法分离测定硒化合物（英文）

提出了一种用高效液相色谱（HPLC）分离和用电感偶合等离子体质谱仪（ICP－MS）或火焰原子吸收光谱仪（FAAS）作元素专一检测器在线测定硒的化学形态的方法。在优化的HPLC条件下,用ESAⅢ阴离子色谱柱（250mm×4．6mm）,以柠檬酸铵为流动相（5．5mmol／L,pH5．5,流速1．5mL／min）,进样量100μL,分离和测定三甲基硒离子、硒代蛋氨酸、亚硒酸和硒酸盐只需8min。HPLC－FAAS在线分析4种硒化合物的检测限为p（Se）=1mg／L。用超声雾化器作ICP－MS的接口,HPLC－ICP－MS在线分析4种硒化合物的检测限分别为P（Se）=0．34μg／L（亚硒酸）,0．18μg／L（硒代蛋氨酸）,0．08μg／L（三甲基硒离子）和0．07μg／L（硒酸盐）。与气动雾化器接口相比,信号强度增加7至31倍。     

离子色谱法测定土壤中植物激素乙烯利

土壤样品中的乙烯利在IonPac AS14分离柱（4mm）,（3．5mmol Na2CO3＋1．0mmol NaHCO3）／L淋洗液的淋洗条件下得到较好的分离。在0～10μg／mL的范围内标准曲线呈线性,检出限为（0．08μg／mL）。精密度好,10．266μg／mL时,保留时间的RSD=0．86％;峰高的RSD=1．1％;峰面积的RSD=1．0％。在此条件下,其它阴离子对乙烯利的检测不干扰,样品的加标回收率为85．6％～87．9％。     

萃取富集-火焰原子吸收法测定环境水中铜、锌、铅、镉

用2-琉基苯并噻唑／醋酸丁酯pH7～8萃取体系，预浓集以后，用火焰原子吸收测定环境水中癌量Cu，Zn，Cd、Pb，回收率在95％～105％，相对标准偏差为2％～5％（x=6)，植出限为Cu0．2μg／L，Zn0．08μg／L、Cd0．03μg／L、Pb0．8μg／L。     

牡丹皮中有效成分丹皮酚的毛细管电泳快速检测新方法

采用毛细管电泳高频电导法对丹皮酚进行了快速分离检测。对电泳介质的种类及浓度、操作电压和进样时间等影响因素进行了优化。最佳条件为：分离介质1．0mmol／LH3BO3-3．0mmol／L三乙胺-10％CH,OH（pH=8．0）,分离电压20．0kV,25．0cm位差虹吸进样8．0s。在该条件下。可在4min内实现对丹皮酚的分离检测。线性范围为2．0～105μg／mL,检出限为0．3μg／mL。成功测定了中药牡丹皮中的丹皮酚,回收率达94％～99％。方法简便、快速、灵敏,可用于药物分析。     

HPLC-ICP-MS测定中药中砷的形态

报道了高效液相色谱-电感耦合等离子体质谱（HPLC—ICP-MS）联用技术测定中药中砷的形态，采用阴离子交换柱，以0．2mmol／L EDTA和2mmol／L NaH2PO4的溶液为流动相，pH6．0，流速为1．0mL／min，成功分离了亚砷酸（AsⅢ）、砷酸（AsV）、甲基砷（MMA）和二甲基砷（DMA）。检出限分别为0．67μg／L（AsⅢ），0．85μg／L（DMA），0．43μg／L（MMA），0．70μg／L（AsV）。中药样品经过（1＋1）甲醇和水的溶液超声提取，离心、过滤、氮气吹干甲醇，超纯水定容。样品加标平均萃取回收率分别为：92．8％（AsⅢ），108％（DMA），104％（MMA），101％（AsV），相对标准偏差（RsD，n=7）均小于10％。     

高效液相色谱法测定红葡萄酒中白藜芦醇的四种异构体

将红葡萄酒用β-葡萄糖苷酶水解处理,使其中的白藜芦醇甙转换成白藜芦醇。采用高效液相色谱法测定水解前后顺、反式白藜芦醇含量的变化,从而计算出葡萄酒中白藜芦醇的4种异构体的含量。色谱柱为Symmetry C18柱(3.9 mm i.d.×150 mm),流动相为乙醇-0.05%乙酸水溶液(体积比为23∶77),紫外检测波长为306 nm。实验结果表明:白藜芦醇的4种异构体在其质量浓度为0.2~50.0 mg/L时均有良好的线性关系(r>0.999),白藜芦醇及其甙的顺、反异构体的最小检出量分别为:0.81     

Isocratic chromatography of resveratrol and piceid after previous generation of fluorescent photoproducts: wine analysis without sample preparation

Resveratrol and its 3-glucoside (piceid), are stilbene-like molecules produced by plants. Both of them are weakly fluorescent, but highly fluorescent compounds are obtained when their hydroethanolic solutions are UV-irradiated, which implies a substantial improvement in the sensitivity of analytical methods. Experimental design (central composite design) together with the response surface methodology have been used to find optimum conditions for the fast, sensitive, and precise chromatographic analysis (with isocratic elution) of resveratrol and piceid in wine samples. These compounds have been UV-transformed into their respective photoproducts, which have been separated in a C18 column (Novapack C(18) 150x3.9 mm, 4 microm) by isocratic elution, using a mobile phase made up of acetonitrile and 4.1 vol% aqueous acetic acid, 19:81 v/v, at a flow rate of 0.8 mL/min, and fluorimetrically detected at 364 nm (lambda(exc) = 260 nm). Detection limits (S/N = 3) are 0.29 and 0.28 microg/L for resveratrol and piceid, respectively. The method has been applied to the analysis of these compounds in wine samples without a clean-up step. The analysis is completed in only 20 min. The standard addition method has been applied to the analysis of a commercial red wine and average recoveries near 100% were obtained for resveratrol and piceid. Three wine pools were satisfactorily analysed by external calibration.     

Supercritical fluid extraction of resveratrol from grape skin of Vitis vinifera and determination by HPLC

Supercritical fluid extraction of resveratrol from grape skin of Vitis vinifera was studied. Extraction variables such pressure, modifier concentration (ethanol), and extraction time were optimised. Final extraction conditions were: 40 degrees C, 150 bar, 7.5% ethanol and extraction time 15 min. Extraction recovery and precision (variation coefficient between 0.2 and 1.0%) were calculated. The resveratrol content in the ethanolic extract was determined by HPLC with UV detection at 306 nm. Acetic acid-methanol-water was used as the mobile phase, and C-18 and C-8 columns were tested, instrumental parameters were optimised, and analytical parameters were calculated (lineal interval 0-75 mg l(-1), detection limit 0.1 mg l(-1), sensitivity 125530 mg(-1) mg l(-1), coefficient variation 0.8-1.6%). Six different varieties of grape skin, from the same geographical area and representative of the wine elaboration, were analysed.     

HPLC-F analysis of melatonin and resveratrol isomers in wine using an SPE procedure

An original analytical method has been developed for the determination of the antioxidants trans-resveratrol (t-RSV) and cis-resveratrol (c-RSV) and of melatonin (MLT) in red and white wine. The method is based on HPLC coupled to fluorescence detection. Separation was obtained by using a RP column (C8, 150 mm x 4.6 mm id, 5 mum) and a mobile phase composed of 79% aqueous phosphate buffer at pH 3.0 and 21% ACN. Fluorescence intensity was monitored at lambda = 386 nm while exciting at lambda = 298 nm, mirtazapine was used as the internal standard. A careful pretreatment of wine samples was developed, using SPE with C18 cartridges (100 mg, 1 mL). The calibration curves were linear over the following concentration ranges: 0.03-5.00 ng/mL for MLT, 3-500 ng/mL for t-RSV and 1-150 ng/mL for c-RSV. The LOD values were 0.01 ng/mL for MLT, 1 ng/mL for t-RSV and 0.3 ng/mL for c-RSV. Precision data, as well as extraction yield and sample purification results, were satisfactory. Thus, the method seems to be suitable for the analysis of MLT and resveratrol isomers in wine samples. Moreover, wine total polyphenol content and antioxidant activity were evaluated.     

Simplified procedure for the determination of sotalol in plasma by high-performance liquid chromatography

A simple, specific and rapid reversed-phase high-performance liquid chromatographic (HPLC) procedure for sotalol determination is described requiring small plasma volumes. The high recovery of sotalol from plasma and the high precision of measurement obviate the need for an internal standard. Plasma samples (300 microliters) were deproteinised with 50 microliters of 70% (w/w) perchloric acid in disposable glass tubes. After vortex-mixing and centrifugation, 30 microliters of 4 M K2HPO4 were added followed by gentle shaking. A 20-microliters aliquot was then injected (by autosampler) for HPLC analysis. Chromatography was performed on a glass-lined 250 mm x 4 mm 5-micron C18 steel column. The mobile phase was 6% (v/v) acetonitrile in 0.08 M KH2PO4 buffer (pH 4.6). The flow-rate was 0.8 ml/min. Detection was by fluorescence with excitation and emission wavelengths at 235 and 310 nm, respectively. The retention time for sotalol was 7.1 min. Calibration was linear from 0.16 to 10 micrograms/ml in plasma (r greater than 0.999 for detector response to sotalol). The minimum concentration for quantitation was 0.08 micrograms/ml [within assay coefficient of variation (C.V.) less than 5%]. Recovery was near quantitative (greater than 98%) and replicate (intra-assay precision was less than 5% C.V.). Analysis of samples (n = 10) at concentrations of 0.42 and 4.2 micrograms/ml gave mean values of 0.44 and 4.3 micrograms/ml, respectively. The inter-assay C.V. values were 4.5 and 2.2%, respectively. Other clinically used antiarrhythmic drugs did not interfere. This assay can be performed using other commercial C18 analytical columns by suitable adjustment of mobile phase flow-rate and acetonitrile composition.     

高效液相色谱法测定人血清中阿西美辛和吲哚美辛

摘要：建立了测定人血清中阿西美辛及其活性代谢物吲哚美辛的高效液相色谱法。分析柱为Spherisorb-C8（5μm）,4.6mm×250mm,流动相为V（醋酸盐缓冲液,pH4.6）:V（乙腈）:V（甲醇）=55:40:5,流速1.0mL/min,检测波长254nm。血清中药物质量浓度为12.5μg/L～1.6mg/L时,阿西美辛、吲哚美辛峰高与内标甲苯磺丁脲峰高比值和质量浓度呈良好的线性关系;阿西美辛日内、日间变异系数分别为3.6％和5.6％,平均回收率为78.3％;吲哚美辛日内、日间变异系数分别为2.4     

高效液相色谱法测定萨拉沙星

采用高效液相色谱法测定了萨拉沙星。色谱柱为μ－BondapakTMC18柱（3．9mm×300mm）,流动相为V（乙腈）：V（甲醇）：V（2mmol／L磷酸,用三乙胺调pH3．5）＝30：5：65,用二极管阵列检测器检测,检测波长278nm,得到了满意的分离效果。     

重楼中薯蓣皂甙元的反相高效液相色谱测定

采用高效液相色谱法测定了重楼中薯蓣皂甙元的质量分数。样品先经甲醇提取,再经酸水解,将重楼甾体皂甙转变成薯蓣皂甙元,以ＳｙｍｍｅｔｒｙＣ８柱为色谱柱,以Ｖ（乙腈）∶Ｖ（水）＝７５∶２５溶液为流动相,检测波长２０３ｎｍ,重复性较好,结果令人满意。     

熊胆中磷脂类化合物的等梯度高效液相色谱法分离分析

摘要：建立了测定熊胆中3种主要磷脂组分即磷脂酰胆碱（PC）、磷脂酰肌醇（PI）、磷脂酰乙醇胺（PE）的高效液相色谱法。将熊胆风干后研成粉末,经V（氯仿）:V（甲醇）=1:4提取液处理后,在P-ESilica柱上进行HPLC分析。流动相为V（乙腈）:V（甲醇）=76:24,流速1.5mL/min,紫外检测波长205nm。PC的平均回收率为89.30％,相对标准差RSD=2.0％。在精密度实验中,PI,PC,PE保留时间的RSD分别为3.9％,1.2％,1.9％,峰面积的RSD分别为1.6％,0.89％,2.     

非水反相高效液相色谱法分离测定枸杞子中的类胡萝卜素

采用非水反相高效液相色谱法在ＯＤＳ柱上比较了不同流动相系统对枸杞子中类胡萝卜素的分离效果,探索了枸杞子中类胡萝卜素的最佳分离条件。