反相高效液相色谱法快速测定7种四环素类抗生素

建立了一种反相高效液相色谱梯度洗脱分离测定四环素类药物的新方法。采用DiamonsilTM C1 8ODS(2 5 0mm× 4 .6mmi.d ,5 μm)色谱柱 ,以甲醇 乙腈 0 .0 1mol/L草酸为流动相 ,流速 1.0mL/min ,2 70nm检测 ,在10min内分离检测四环素等 7种化合物。同时还研究了流动相组成、梯度条件、pH值、草酸浓度等因素对分离效果的影响。     

反相离子对高效液相法分离不同种类的磷脂酰胆碱

 采用反相离子对高效液相 (RP IP HPLC)法分离分析了不同种类的磷脂酰胆碱 (PC) ,柱为PERKIN ELMER/HS 5C18柱 ,流动相为甲醇 乙腈 水 (70∶2 2∶8,体积比 ) (内含 15mmol/L四甲基磷酸铵离子对试剂 ,pH 7) ,流速 2mL/min ,在 2 0 8nm波长处检测 ,该法成功地分离了 7种PC。     

β-环糊精流动相添加剂法分离测定积雪草总苷元中的羟基积雪草酸

以β-环糊精为流动相添加剂,采用反相高效液相色谱法于C18反相柱上拆分了羟基积雪草酸及其同分异构体,建立了积雪草样品中羟基积雪草酸含量的测定方法,探讨了β-环糊精浓度、流动相pH对同分异构体分离度的影响。结果表明:当流动相为甲醇-水（体积比为65∶35）,pH为4时,同分异构体的分离度随着β-环糊精浓度的增加而增大;羟基积雪草酸在0.1~5.0 g/L范围内,峰面积与浓度呈线性关系（r2=0.9989）,说明该法适用于羟基积雪草酸的含量检测及有关药品的质量控制。     

高效液相色谱手性流动相添加剂分离西孟坦对映体

以 β 环糊精作为手性流动相添加剂 ,研究了DL 西孟坦在反相HPLC系统中的拆分。考察了缓冲盐的浓度、pH、β 环糊精的浓度、流动相中甲醇的比例、流动相流速和温度对手性分离的影响 ,建立了 β 环糊精动态手性固定相法分离西孟坦对映体的方法。色谱条件为 :ZirchromKromasilODS 1(5 μm ,15 0mm× 4 .6mm)色谱柱 ,流动相为 2 0mmol/L磷酸盐缓冲液 (pH 6 .0 )含 12mmol/Lβ 环糊精∶甲醇 (70∶30 ,V/V) ,流速为 0 .8mL/min ,温度为 17℃。DL 西孟坦对映体的保留时间分别为 2 2 .5和 2 4 .5min ,分离度为 1.5 7。     

高效液相色谱法快速测定血清中的芳香族氨基酸

采用高效液相色谱-紫外检测法分离测定了血清中的芳香族氨基酸。采用的色谱柱为Waters Nova-Pak C18柱(4 μm,150 mm×3.9 mm i.d.),流动相为乙腈-水(体积比为6∶94,pH 3.4)溶液,流速为1.0 mL/min,检测波长为215 nm。血清标本经5%(体积分数)高氯酸溶液去除蛋白质后取上清液直接进样,10 min内完成测定。探讨了流动相的pH及其有机相的比例、蛋白质沉淀剂以及检测波长等因素对分离度和灵敏度的影响。考察了其他10余种氨基酸、多巴胺类等物质对目标组分检测的     

微乳液相色谱法同时分离7种水溶性维生素

采用微乳液相色谱法同时分离7种水溶性维生素(V_(B1)、V_(B2)、V_(B6)、VB_(12)、叶酸、烟酰胺和VC)。考察了微乳流动相体系中表面活性剂、油相、助表面活性剂的种类以及流动相的pH值、柱温等对水溶性维生素分离的影响。优化后微乳体系的组成为:十二烷基硫酸钠(SDS)/聚氧乙烯月桂醇醚(Brij35)/正丁醇/乙酸乙酯/水(质量比为2∶60∶66∶8∶864)。色谱柱为Agilent TC C18(250 mm×4.6 mm,5μm),柱温为30℃,检测波长为254 nm,流速为0.5mL/min。7种水溶性维生素在20 min内达到基线分离。在4~36 mg/L范围内,7种水溶性维生素的质量浓度与峰面积的相关系数均大于0.999 1。不同添加水平下,V_(B1)、V_(B2)、V_(B6)、VC和烟酰胺的平均回收率为93.9%~102.9%。该方法可用于食品和药品中的多种水溶性维生素的分离、鉴别及快速测定。     

反相高效液相色谱法同时测定6种氟喹诺酮类药物

建立了一种反相高效液相色谱-荧光检测法同时测定血浆中6种氟喹诺酮类药物(FQS)的方法。考察了6种FQS的保留值与流动相组成及pH值的关系, 优化了色谱条件及样品前处理方法。确定了以Chira Dex为色谱柱、乙腈-甲醇-Britton-Robinson缓冲液(体积比为73∶7∶20, pH 5.7)为流动相的最佳条件。该法用于血浆样品中FQS的测定,其回收率高于99.0%。该法简便、快速、准确、灵敏度高、重现性好。     

高效液相色谱法同时测定多种食品添加剂

 采用反相高效液相色谱法 ,一次进样、同时测定食品中的人工合成甜味剂 (糖精钠、安赛蜜、甜味素 )、防腐剂(苯甲酸、山梨酸 )、咖啡因、可可碱和茶碱。以AlltechEconosphereC18柱 (15 0mm× 4 6mmi.d .,3μm)为分离柱 ,10mmol/LNaH2 PO4 (pH 4 0 0 ) 乙腈 (体积比为 90∶10 )为流动相 ,采用二极管阵列检测器进行检测。整个分离过程在 2 3min内完成。样品平均加标回收率为 78 5 %～ 10 7 2 %。     

动物组织中金霉素残留测定的高效液相色谱柱后衍生反应研究

建立了动物组织中金霉素残留测定的高效液相色谱柱后衍生法,研究了镁离子和草酸体系对金霉素荧光强度的影响。结果表明,镁离子浓度和草酸浓度为1∶1.2时,金霉素的荧光强度最强。动物组织样品以5%高氯酸提取,正己烷脱脂,C18净化,Hy-persil ODS C18(250×4.6 mm,5μm)分离,流动相为甲醇∶0.05 mol/L草酸=80∶20(V/V),流速为0.7 mL/min,柱后0.05 mol/L乙酸镁衍生,流速为0.1 mL/min,紫外检测器和荧光检测器同时测定,提高了金霉素残留定量灵敏度。紫外检测波长365nm,荧光检测波长eλx=360 nm,eλm=520 nm。     

固相萃取富集-高效液相色谱分离和测定邻甲苯胺和邻硝基甲苯

建立了以固相萃取技术进行富集 ,高效液相色谱进行分离和检测邻甲苯胺和邻硝基甲苯的方法。污染水中的邻甲苯胺和邻硝基甲苯采用Sep pakC1 8萃取柱进行固相萃取。色谱分离条件是 :Shim PackCLCODS(1 5 0mm× 4 .6mmid ,5 μm)柱为分析柱 ,甲醇 水 =60∶4 0 (V V)为流动相 ,流速为 1 .0mL min,邻甲苯胺和邻硝基甲苯的紫外检测波长分别为 2 3 0nm和 2 5 4nm ,本法具有良好的灵敏度和重现性。     

Determination of tetracyclines in ovine milk by high-performance liquid chromatography with a coulometric electrode array system

A method has been developed to analyze residual tetracyclines (TCs) (oxytetracycline (OTC), tetracycline (TC), chlortetracycline (CTC), methacycline (MTC), doxycycline (DC)) in ovine milk, using high-performance liquid chromatography (HPLC) with a coulometric electrode array system. The samples were pretreated, using liquid-liquid extraction based on hexane. The chromatography was performed, using a C18 column (150 mm x 4 mm i.d. and 5 microm) with a mobile phase: sodium phosphate monobasic dihydrate (pH 2.2, 0.05 M)-acetonitrile (78:22, v/v). The flow rate of mobile phase was kept constantly at 1ml/min. The residues were monitored by an ESA electrochemical detector. Potentials of four electrodes in series were set at 400, 660, 680 and 700 mV, respectively. The first electrode was set to remove those interfering substances that may co-elute with TCs and the other three electrodes were used for quantification. The maximal potential of our detection was 700 mV. Calibration curve showed good linearity and the detection limit of TCs was 12.5, 20, 25, 10 and 25 ng/ml, respectively. Optimization of the pH of the mobile phase, the proportion of acetonitrile and the pH of the pretreatment were also performed. Recoveries of TCs from spiked samples were more than 88% and the relative standard deviations were less than 4.3%. This method was reliable, sensitive, economical and suited for routine monitoring of TC residues in ovine dairy milk.     

Improvement of chemical analysis of antibiotics. X. Determination of eight tetracyclines using thin-layer and high-performance liquid chromatography

Analytical methods for eight tetracyclines (TCs) were established using silica gel high-performance thin-layer chromatography (HPTLC), reversed-phase thin-layer chromatography (RP-TLC) and high-performance liquid chromatography (HPLC). Good separations of eight TCs were obtained using chloroform-methanol-5% disodium ethylenediaminetetraacetate solution (65:20:5) (lower layer) and methanol acetonitrile 0.5 M oxalic acid solution (1:1:4) (pH 3.0) on silica gel HPTLC and C8 TLC plates, respectively. A combination of HPTLC and RP-TLC made possible the identification of the eight TCs. Each calibration graph was linear between 0.1 and 1.0 microgram using UV densitometry except for rolitetracycline. For detection reagents, the diazonium salts including Fast Violet B gave variously coloured spots with the eight TCs and good sensitivities were obtained except with minocycline. In HPLC, the simultaneous analysis of the eight TCs on a C8 column was possible using methanol-acetonitrile-0.01 M oxalic acid solution (1:1.5:7) adjusted to pH 3.0 as the mobile phase. A linear relationship was obtained between 1.0 and 10 ng using the usual sample preparation except for rolitetracycline. The direct determination of rolitetracycline was possible using tetrahydrofuran, dimethyl sulphoxide and the mobile phase as solvents for preparation of the sample. For the determination of residual rolitetracycline, it was effective to measure the amount of rolitetracycline as tetracycline by HPLC, HPTLC and RP-TLC after conversion of rolitetracycline to tetracycline by incubating for 5 min in methanol at 50 degrees C.     

高效液相色谱化学发光法检测牛奶中残留四环素类化合物的研究

基于四环素类抗生素药物中的四环素(TC)、土霉素(OTC)、金霉素(CTC)和多西环素(DC)能够强烈增敏通过恒电流电解方法在线电生BrO^－和鲁米诺之间产生的化学发光, 提出了一种高效液相色谱(HPLC)化学发光(CL)法检测4种四环素类抗生素药物的新方法. 以Nucleosil RP-C₁₈ (250 mm×4.6 mm, i.d., 5 μm, pore size, 100 Å)为色谱柱, 0.05 mol• L^－1磷酸二氢钾(pH 2.5)-乙腈(30∶70, V∶V)为流动相, 流速1.2 mL/min, 柱温25 ℃, 同时分离检测四种抗生素的总时间为11 min. 研究并优化了流动相、电生试剂化学发光检测的条件. 四种抗生素的检出限为0.002～0.008 μg•mL^－1 (3σ), 对0.01 μg•mL^－1的四种抗生素测定的相对标准偏差为2.0%～3.6% (n＝11). 该方法已成功应用于牛奶中残留四环素类抗生素含量的分析.     

Determination of tetracycline antibiotics by reversed-phase high-performance liquid chromatography with fluorescence detection.

A highly sensitive method for the determination of tetracycline antibiotics (TCs) using reversed-phase high-performance liquid chromatography with fluorescence detection is presented. This method was based on the use of disodium ethylenediaminetetraacetate (EDTA) and calcium chloride as fluorescence-increasing reagents in the mobile phase. The concentrations of each reagent in the mobile phase greatly influenced the fluorescence intensity of TCs. When the concentration of EDTA and calcium chloride were 25 and 35 mM, respectively, and the pH of the mobile phase was 6.5, the maximum fluorescence intensity was obtained. The column temperature hardly influenced the fluorescence intensity. At 3.75 ng of TCs injected, the precision (relative standard deviation) ranged from 1.12 to 2.20%. In the range 0.075-37.5 ng for tetracycline and oxytetracycline and 0.225-37.5 ng for chlortetracycline, a linear response was observed. The detection limits of this method were 49-190 pg for three different TCs. The proposed method was applied to the determination of one of the TCs in pharmaceuticals by the internal standard method using other TCs as internal standards and was also applied to determination of TCs added to fish tissue.     

Analysis of streptokinase by validated liquid chromatography methods and correlation with an in vitro bioassay

Reversed‐phase and size‐exclusion liquid chromatography methods were validated for the assessment of streptokinase. The reversed‐phase method was carried out on a Jupiter C₄ column (250 mm × 4.6 mm id) maintained at 25°C. The mobile phase consisted of 50 mM sodium sulfate solution pH 7.0 and methanol (90:10, v/v), run isocratically at a flow rate of 0.8 mL/min. The size‐exclusion method was carried out on a Protein KW 802.5 column (300 mm × 8.0 mm id), at 25°C. The mobile phase consisted of 40 mM sodium acetate solution pH 7.0, run isocratically at a flow rate of 1.0 mL/min. Retention times were 19.3 min, and 14.1 min, and calibration curves were linear over the concentration range of 0.25–250 μg/mL (25.75–25 750 IU/mL) (r ² = 0.9997) and 5–80 μg/mL (515–8240 IU/mL) (r ² = 0.9996), respectively, for reversed‐phase and size exclusion, with detection at 220 and 204 nm. Chromatographic methods were employed in conjunction with the in vitro bioassay for the content/potency assessment of Streptokinase, contributing to improve the quality control and ensure the efficacy of the biotherapeutic.     

Hydrophilic interaction chromatography separation mechanisms of tetracyclines on amino-bonded silica column

Effects of mobile-phase variations on the chromatographic separation on amino-bonded silica column in hydrophilic interaction chromatography (HILIC) were investigated for four zwitterionic tetracyclines (TCs): oxytetracycline, doxycycline, chlortetracycline, and tetracycline. A mixed-mode retention mechanism composed of partitioning, adsorption, and ion exchange interactions was proposed for the amino HILIC retention process. Buffer type and pH significantly influenced the retention of TCs, but showed similar separation selectivity for the tested analytes. Experiments varying buffer salt concentration and pH demonstrated the presence of ion exchange interactions in TCs retention. The type and concentration of organic modifier also affected the retention and selectivity of the analytes, providing direct evidence supporting the Alpert retention model for HILIC. The retention time of the analytes increased in the following order of organic modifiers: tetrahydrofuran < methanol < isopropanol < acetonitrile. The linear relationships of logk' versus %water (v/v) curve and logk' versus logarithm of %water (v/v) in the mobile phase indicated that TCs separation on the amino phase was controlled by partitioning and adsorption. The developed method was successfully utilized in the detection of TCs in both river water and wastewater samples using solid-phase extraction (SPE) for sample cleanup.     

Ultra high performance liquid chromatography method development for separation of omeprazole and related substances on core‐shell columns using a Quality by Design approach

An updated and improved method for analysis of omeprazole/esomeprazole and related substances on core‐shell columns was developed using Fusion LC Method Development?. The method was optimized with respect to column type, column temperature, mobile phase pH level, and gradient time. Four different core‐shell columns were examined to develop a method suitable for both high performance‐ and ultra‐high performance liquid chromatography using a Quality by Design approach. The final method offers two alternative columns: Poroshell EC C18 (3.0 × 100 mm, 2.7 µm) or Poroshell HPH (3.0 × 100 mm, 2.7 µm) with the same gradient elution condition and mobile phase composition. Total run time is 18 min with 12 min of gradient elution. Phosphate buffer (15 mM, pH 7.8) is selected as the aqueous mobile phase and acetonitrile as the organic mobile phase. Column temperature is set at 40°C and ultraviolet detection at 302 nm. Furthermore, by studying parameters in a systematic way, an understanding of the effect of the input parameters enhances the method robustness and should allow for regulatory flexibility in terms of post‐approval changes. Compared to the current United States Pharmacopeia method, the updated method is faster, more efficient and performs well above acceptance criteria.     

反相高效液相色谱法测定牙膏中的甘草次酸

采用反相高效液相色谱法测定了牙膏中的甘草次酸。在ＹＷＧ Ｃ１８（４０ｍｍｉ．ｄ．×２５０ｍｍ,１０μｍ）色谱柱上,以Ｖ（甲醇）∶Ｖ（００１ｍｏｌ／ＬＫＨ２ＰＯ４）＝８５∶１５（ｐＨ３０）的溶液为流动相,流速为１０ｍＬ／ｍｉｎ,紫外检测波长为２５４ｎｍ,室温下检测。甘草次酸用甲醇提取。甘草次酸的平均回收率为９９６１％～１０１６７％,样品测试相对标准偏差为１８５％～３１６％。方法操作简便、快速和准确。     

高效液相色谱手性流动相添加法拆分阿卓乳酸对映体

采用C₁₈反相色谱柱,以磺丁基醚-β-环糊精（SBE-β-CD）作为手性流动相添加剂,建立了阿卓乳酸对映体的高效液相色谱拆分方法。考察了环糊精衍生物类型、手性添加剂浓度、流动相pH、流速和柱温对手性分离的影响,同时探讨了高效液相色谱采用磺丁基醚-β-环糊精分离阿卓乳酸对映体的分离机制及包结常数,确定了色谱条件为YMC-Pack ODS-A C₁₈色谱柱（250 mm×4.6 mm,5 μm）,流动相为含25 mmol/LSBE-β-CD的0.1 mol/L磷酸盐缓冲液（pH 2.68）-乙腈（90：10,v/v）,流速为0.6 mL/min,柱温为30 ℃,紫外检测波长为220 nm。对映体的保留时间分别为26.65和28.28 min,分离度为1.68。本方法分离度好,简便易行,且比使用手性固定相分离更加经济。