大体积进样-非匀强电场扫集微乳毛细管电动色谱法测定化妆品中糖皮质激素

建立了一个简单有效的微乳毛细管电动色谱(MEEKC)在线富集-大体积进样(LVSI)与非匀强电场扫集(REFS)联用测定化妆品中4种糖皮质激素(泼尼松、氢化可的松、泼尼松龙和倍他米松)的方法。MEEKC的缓冲体系组成为:2.4%SDS,0.6%正辛烷,6.6%正丁醇,30 mmol/L硼酸盐缓冲液(pH 8.2),分离电压为9.6 kV,进样压力为12.3 kPa,进样时间为95 s,检测波长为230 nm。在最优实验条件下,4种糖皮质激素的富集倍数为853~933倍,在0.015~14 mg/L范围内呈线性关系,检出限(S/N=3)为4~8μg/L。应用此方法分析了化妆品样品,回收率为93.7%~103.8%,相对标准偏差(n=5)均不大于4.4%。     

场放大进样-胶束毛细管电泳法测定化妆品中3种糖皮质激素

采用场放大进样-胶束毛细管电泳法对化妆品中氢化可的松、泼尼松和乙酸氢化可的松3种糖皮质激素进行了分离测定。电泳介质为0.20mmol.L-1硼砂缓冲溶液(pH 9.0),运行电压为-20kV,进样电压-20kV,进样时间45s,进水压力3kPa,进水时间20s,检测波长250nm。在优化试验条件下,氢化可的松、泼尼松和乙酸氢化可的松的检出限分别(3S/N)为0.015,0.017,0.017mg.L-1。应用此方法分析了化妆品样品,测得回收率在93.8%～107%之间,测定值的相对标准偏差(n=5)均小于5.1%。     

离子液体作为添加剂的反向微乳毛细管电动色谱分析化妆品中的糖皮质激素

建立了以离子液体为添加剂的反向微乳毛细管电泳(IL-MEEKC)法分离测定化妆品中氢化可的松、泼尼松和醋酸氢化可的松3种糖皮质激素的方法.微乳毛细管电泳的最佳缓冲体系组成为:2.4% SDS+6.6%正丁醇+0.5%正辛烷+35 mmol/L BMIM-BF4+20 mmol/L磷酸二氢钠缓冲液(pH 2.2);运行电...     

阴离子选择性耗尽进样-胶束扫集毛细管电泳法对痕量醋酸氢化可的松的测定

联用阴离子选择性耗尽进样和胶束扫集两种在线富集技术,建立了胶束毛细管电泳方法测定化妆品中醋酸氢化可的松的方法。讨论了SDS浓度、样品基体、进样电压、进水时间和进样时间对富集和分离的影响。优化的实验条件:以120 mmol/L SDS-20 mmol/L NaH2PO4(pH2.2)-10%(体积分数)甲醇为缓冲体系,分离电压-20 kV,进样电压-20 kV,进样时间80 s,进水时间200 s,测量波长250 nm。在该实验条件下,醋酸氢化可的松的富集倍数比普通毛细管电泳法提高了约173倍。方法的线性范围为0.05~5.0 mg/L,检出限为12.6μg/L。该方法用于化妆品中醋酸氢化可的松含量的测定,回收率为98%~105%,相对标准偏差均小于4.0%(n=4)。     

微乳毛细管电色谱电动进样-场放大堆积法检测化妆品中糖皮质激素

采用反向微乳毛细管电色谱电动进样联用场放大堆积,建立了在线富集检测化妆品中6种糖皮质激素分析方法。微乳毛细管电色谱缓冲体系为2.4%(w/w)十二烷基硫酸钠,6.6%(w/w)正丁醇,0.6%(w/w)正辛烷,20 mmol/L磷酸盐缓冲液(pH 2.2),分离电压!20 kV,进样!20 kV×54 s,进水15 kPa×40 s,检测波长240 nm。讨论了样品基质、进样时间和电压、水柱长度对富集效果的影响。在优化条件下,6种激素的富集倍数分别为100~186倍,在0.05~15.0 mg/L范围内呈线性关系,相关系数0.9986~0.9997。检出限为20~60μg/L(S/N=3),标准加入量为50μg/L时平均回收率85.9%~103.8%,相对标准偏差均小于5.8%。迁移时间和峰高的日内精密度分别为2.2%和7.9%,日间精密度分别为2.9%和9.0%。     

离子液体对胶束电动色谱胶束微结构以及分离效果的影响

考察了离子液体对胶束电动色谱胶柬微结构以及分离效果的影响.研究结果表明,离子液体使胶束的表面电荷密度变小、粒径变大及其内核极性增大.以泼尼松、氢化可的松和泼尼松龙为分析对象,氢化可的松与泼尼松龙在十二烷基硫酸钠(SDS)胶束体系中不能实现分离.而在SDS-离子液体混合介质(20 mmol/L SDS-10 mmol/L...     

离子液体和β-环糊精修饰反向微乳毛细管电动色谱分析化妆品中的激素

建立了以离子液体和β-环糊精为添加剂的反向微乳毛细管电泳(MEEKC)法分离测定化妆品中丙酸氟替卡松、曲安奈德、醋酸可的松、地塞米松、氢化可的松和泼尼松6种激素的方法.在优化的实验条件下,6种物质于12min内达到基线分离,丙酸氟替卡松在2.0～200mg/L范围内线性关系良好,其它组分在2.0 ～ 500mg/L范围内线性关系良好,检出限(S/N =3)分别为0.75、0.81、0.66、0.68、0.74、0.86 mg/L.方法用于化妆品样品测定,加标回收率在93.5％～105％之间,RSD均小于4.3％(n=3).     

鼠李糖脂的合成及pH值对其表面活性和微乳微结构的影响

从铜绿假单胞菌发酵液中提取纯化鼠李糖脂生物表面活性剂. 用高效液相色谱-电喷雾质谱法(HPLC-ESI-MS)对鼠李糖脂提取物的组成进行了测定. 用临界胶束浓度(CMC)分析了pH值对其表面活性的影响, 用微乳液滴粒径和灼电位考察了pH值对鼠李糖脂/正庚烷/硼砂缓冲液微乳体系微结构的影响. 结果表明, 在弱碱性条件下(pH7.5-9.5), pH的变化对鼠李糖脂的表面活性和微乳微结构均有显著影响. pH小于9.0时, CMC随着pH的升高而降低, 在pH 9.0处达到最低. pH大于9.0时, CMC随着pH值的升高而逐渐升高. 这是氢键和极性头基间的静电排斥力共同作用的结果. 微乳液滴的粒径及灼电位绝对值都随pH值的升高呈增大趋势, 只在pH 9.0处例外. 少量十二烷基硫酸钠(SDS)或正丁醇的加入都使微乳粒径明显增大.     

场放大进样-胶束扫集毛细管电脉法测定痕量泼尼松

建立了胶束毛细管电动色谱在线富集技术测定药品中痕量的泼尼松的方法。在胶束扫集的基础上联用场放大进样,使泼尼松的富集倍数提高了136倍;检出限由原来的2.7mg/L降至20μg/L。胶束扫集毛细管电泳缓冲体系为120mmol/LSDS、10mmol/LNaH2PO4(pH2.5)10%乙腈(V/V)。分离电压-20kV,进样电压-20kV,进样时间70s,进水时间180s,检测波长250nm。同时讨论了SDS浓度、样品基质pH、进样电压、进水时间和进样时间对分离效果的影响。实验结果显示:在优化实验条件下,样品的检测仅需8min,泼尼松在0.05～10mg/L的范围内线性关系良好(r=0.998)。回收率在89.4%～106%之间,相对标准偏差在2.1%～2.6%之间,可用于各种中药制剂中泼尼松的含量测定。     

加压毛细管电色谱-紫外检测法分析糖皮质激素及其在头发检测中的应用

采用反相加压毛细管电色谱与紫外检测联用技术,建立了一种高效、简便的糖皮质激素分析方法,适用于头发中糖皮质激素的检测。使用C18反相色谱柱,流动相为pH 8.0, 1.5 mmol/L的Tris-乙腈(65:35, v/v),检测波长为245 nm、分离电压为~10 kV、反压为10.5 MPa、泵流速为0.05 mL/min,进行等度洗脱,倍他米松、地塞米松、泼尼松、泼尼松龙、醋酸泼尼松龙、醋酸氢化可的松、醋酸可的松、皮质脂酮等8种激素在20 min内实现快速分离。各组分的质量浓度线性范围达到3个数量级,检出限(S/N=3)在μg/g水平,迁移时间和峰面积的相对标准偏差(RSD)分别小于4.8%和7.4%。将所建立方法应用于头发样品分析,检测前采用蛋白酶水解提取和净化处理样品,不同浓度糖皮质激素的回收率为71%～85%。该研究为糖皮质激素药物暴露监测以及压力检测提供了新手段,有望用于滥用药物的控制和临床诊断。     

Separation and determination of two sesquiterpene lactones in Radix inulae and Liuwei Anxian San by microemulsion electrokinetic chromatography

A novel microemulsion electrokinetic chromatography (MEEKC) method for separating and determining two sesquoterpene lactones, alantolactone (AL) and isoalantolactone (IAL), in Radix inulae and Liuwei Anxian San has been developed. The effects of several important factors such as internal organic phases, concentration of microemulsion, concentration of acetonitrile, injection time and running voltage were systematically investigated to determine the optimum conditions. The optimum microemulsion system was composed of n-hexane (0.32% w/w), SDS (1.24% w/w), 1-butanol (2.64% w/w), acetonitrile (10% w/w) and 10 mm sodium tetraborate buffer (85.80% w/w, pH 9.2). The applied voltage was 20 kV. The analytes were detected at 214 nm. Regression equations revealed linear relationships (correlation coefficients 0.9950 for AL and 0.9946 for IAL) between the peak area of each analyte and the concentration. The limits of detection (defined as a signal-to-noise ratio of about 3) were approximately 0.45 microg/mL for AL and 0.56 microg/mL for IAL. The levels of the analytes were successfully determined with recoveries ranging from 98.2 to 104.3%. Furthermore, a simple and effective extraction method, with methanol in an ultrasonic water bath for 60 min, was used for sample preparing. Also, MEEKC was compared with micellar electrokinetic chromatography (MEKC) and shown better separation results.     

Enantioseparation of chiral tropa alkaloids by means of cyclodextrin-modified microemulsion electrokinetic chromatography

CD-modified microemulsion EKC as a CE technique has been applied to the chiral separation of atropine, scopolamine, ipratropium and homatropine. Enantioseparations of these tropa alkaloids were optimized by using a standard oil-in-water (O/W) microemulsion and varying the nature and concentration of CD additives as well as of the organic modifier (methanol, 2-propanol or ACN) whilst keeping the applied voltage of 15 kV and capillary temperature of 30 degrees C constant. The standard (O/W) microemulsion BGE solution consisted of 0.8% w/w octane, 6.6% w/w 1-butanol, 2.0% w/w SDS and 90.6% w/w 10 mM sodium tetraborate buffer (pH 9.2). Enantioseparations with high resolution and short migration times of all tropa alkaloids were achieved by using heptakis(2,3-di-O-methyl-6-O-sulfo)-beta-CD and sulfated beta-CD in the microemulsion BGE and were superior to corresponding CD-modified CE methods.     

Rapid separation of pharmaceutical enantiomers using electrokinetic chromatography with a novel chiral microemulsion

A novel oil-in-water microemulsion incorporating the chiral surfactant dodecoxycarbonylvaline (DDCV) was used to achieve the rapid enantiomeric separation of pharmaceutical drugs by electrokinetic chromatography (EKC). Incorporation of DDCV into a microemulsion resulted in an elution range more than double that provided the micellar form of the surfactant aggregate. Interestingly, for the same compounds the enantioselectivity provided by the chiral DDCV microemulsions ranged from 1.06-1.30 for the neutral and cationic drugs, which was slightly higher than that provided by chiral DDCV micelles. The use of a low surface tension oil (ethyl acetate) permitted a much lower concentration of chiral surfactant to be employed; this, together with the use of a zwitterionic buffer (ACES) resulted in a very low conductivity microemulsion that allowed a higher separation voltage to be utilized, resulting in rapid enantiomeric separations (< 8 min.). Mobility matching of the buffer cation(s) was used to improve peak shape and efficiencies. In our limited survey of the phase diagram, the optimum composition of the microemulsion buffer was 1.0% (w/v) DDCV (30 mM), 0.5% (v/v) ethyl acetate, 1.2% (v/v) 1-butanol and 50 mM ACES buffer at pH 7.     

Separation of corticosteroids by microemulsion EKC with diethyl L-tartrate as the oil phase

A novel microemulsion based on a mixture of diethyl L-tartrate (DET) and SDS was developed for the microemulsion EKC (MEEKC) determination of structurally related steroids. The system consisted of 0.5% w/w DET, 1.7% w/w SDS, 1.2% w/w 1-butanol, 89.6% w/w phosphate buffer (40 mM, pH 7.0), and 7% w/w ACN. With an applied voltage of +10 kV, a baseline separation of aldosterone (A), cortisone acetate (CA), dexamethasone (D), hydrocortisone (H), hydrocortisone acetate (HA), prednisolone (P), prednisolone acetate (PA), prednisone (Ps), triamcinolone (T), and triamcinolone acetonide (TA) could be achieved. Under the optimized conditions, the reproducibility of the retention time (n = 4) for most of the compounds was less than +/-0.8% with the exception of A, Ps, and T. The average number of theoretical plates was 18 800 plates/m. The results were compared with those achieved by the modified micellar EKC (MEKC). MEEKC showed obvious advantages over MEKC for the separation of highly hydrophobic substances. To further evaluate the system, we tested the MEEKC method by analyzing corticosteroids in a spiked urine sample.     

Comparison of HPLC and MEEKC for Miconazole Nitrate Determination in Pharmaceutical Formulation

A simple solid phase extraction (SPE) method coupled with high performance liquid chromatography (HPLC) using UV detector and microemulsion electrokinetic chromatography (MEEKC) has been developed and compared for the quantitative determination of miconazole nitrate in pharmaceutical formulation. For HPLC method, two parameters were optimized, namely, the wavelength and the mobile phases. The optimized condition was at the 225 nm wavelength and the mobile phase of ACN:MeOH (90:10 v/v). There are seven MEEKC parameters that were optimized, in this research, which were applied to voltage, temperature, wavelength, sodium dodecyl sulfate (SDS) concentration, buffer pH, buffer concentration and butan-1-ol concentration. The optimum MEEKC condition was obtained using 86.35 % (w/w) 2.5 mM borate buffer pH 9, 0.25 % (w/w) SDS, 0.8 % (w/w) ethyl acetate, 6.6 % w/w butan-1-ol and 6.0 % (w/w) acetonitrile. The combination of SPE using a diol column with HPLC–UV and the MEEKC methods were successfully applied for the determination of miconazole nitrate in a pharmaceutical formulation with the recovery percentage of 98.35 and 92.50 %, respectively.     

Comparison of HPLC and MEEKC for Miconazole Nitrate Determination in Pharmaceutical Formulation

A simple solid phase extraction (SPE) method coupled with high performance liquid chromatography (HPLC) using UV detector and microemulsion electrokinetic chromatography (MEEKC) has been developed and compared for the quantitative determination of miconazole nitrate in pharmaceutical formulation. For HPLC method, two parameters were optimized, namely, the wavelength and the mobile phases. The optimized condition was at the 225 nm wavelength and the mobile phase of ACN:MeOH (90:10 v/v). There are seven MEEKC parameters that were optimized, in this research, which were applied to voltage, temperature, wavelength, sodium dodecyl sulfate (SDS) concentration, buffer pH, buffer concentration and butan-1-ol concentration. The optimum MEEKC condition was obtained using 86.35 % (w/w) 2.5 mM borate buffer pH 9, 0.25 % (w/w) SDS, 0.8 % (w/w) ethyl acetate, 6.6 % w/w butan-1-ol and 6.0 % (w/w) acetonitrile. The combination of SPE using a diol column with HPLC–UV and the MEEKC methods were successfully applied for the determination of miconazole nitrate in a pharmaceutical formulation with the recovery percentage of 98.35 and 92.50 %, respectively.

     

Simultaneous determination of natural and synthetic estrogens by EKC using a novel microemulsion

A novel microemulsion based on sodium bis(2-ethylhexyl) sulfosuccinate (AOT) was developed for the simultaneous determination of natural and synthetic estrogens by microemulsion EKC (MEEKC). The microemulsion system consisted of 1.4% w/w AOT, 1.0% w/w octane, 7.0% w/w 1-butanol and 90.6% w/w 20 mM sodium salt of 3-(cyclohexylamino)-2-hydroxy-1-propanesulfonic acid (CAPSO) and 10 mM phosphate buffer at pH 12.5. A baseline resolution in the separation of estrone, 17beta-estradiol, estriol, estradiol 17-hemisuccinate, etinilestradiol, estradiol 3-benzoate, and estradiol 17-valerate was achieved in comparison to the traditional MEEKC system with SDS in less than 15 min. The optimized electrophoretic conditions included the use of an uncoated-silica capillary of 60 cm of total length and 75 microm id, an applied voltage of 25 kV, a temperature of 25 degrees C and 214 UV-detection. Parameters of validation such as specificity, linearity, accuracy, LOD, LOQ and robustness were evaluated according to international guidelines. Due to its simplicity, accuracy, and reliability, the proposed method can be an advantageous alternative to the traditional methodologies for the analysis of natural and synthetic estrogens in different pharmaceutical forms.     

Separation and on-column preconcentration of some nonsteroidal anti-inflammatory drugs by microemulsion electrokinetic capillary chromatography using high-speed separations

Various strategies have been investigated for separating a group of nonsteroidal anti-inflammatory drugs (NSAIDs) by microemulsion electrokinetic capillary chromatography (MEEKC) using high-speed separations. The parameters that of affect the separation, such as the nature of the oil droplet and the buffer, and the surfactant concentration have been studied. In addition, several organic solvents were used to decrease the retention of the analytes in the oil droplet phase and to improve the resolution of the NSAIDs. The optimum microemulsion background electrolyte (BGE) solution made of 0.8% w/w ethyl acetate, 6.6% w/w butan-1-ol, 6.0% w/w acetonitrile, 1.0% w/w sodium dodecyl sulfate (SDS), and 85.6% w/w of 10 mM sodium tetraborate at pH 9.2 resolved the drugs within 8 min. The short-end injection procedure is an alternative for reducing the analysis time. When this procedure was used, the microemulsion BGE solution consisted of 0.8% w/w ethyl acetate, 6.6% w/w butan-1-ol, 17.0% w/w methanol, 1.0% w/w SDS, and 74.6% w/w of 10 mM sodium tetraborate, pH 9.2, and the NSAIDs were separated within 3 min. The reversed electrode polarity stacking mode (REPSM) technique was applied to the on-line concentration of the NSAIDs. In this technique, the sample matrix was pumped out of the capillary using a polarity-switching step. When this technique was applied, the sensitivity was enhanced up to 40-fold and the limits of detection (LODs) were in the low microg.L(-1) levels.     

A capillary electrophoretic system based on a novel microemulsion for the analysis of coenzyme Q10 in human plasma by electrokinetic chromatography

A new analytical method for determination of coenzyme Q10 (2,3‐dimethoxy‐5‐methyl‐6‐decaprenyl‐1,4‐benzoquinone, CoQ10) in human plasma was developed based on CE using a double tensioactive microemulsion. CoQ10 was quantitatively extracted into 1‐propanol/hexane and quantified by MEEKC. The microemulsion was prepared by mixing 1.4% w/w sodium bis(2‐ethylhexyl) sulfosuccinate, 4% w/w cholic acid, 1% w/w octane, 8.5% w/w butanol, 0.1% w/w PVA and 85% w/w 10 mM Tris buffer at pH 9.0. The optimized electrophoretic conditions included the use of an uncoated silica capillary of 60 cm total length and 75 μm id, an applied voltage of 20 kV, room temperature and 214 nm ultraviolet detection. Selectivity, linearity, LOD, LOQ, precision and accuracy were evaluated as the parameters of validation. Owing to its simplicity and reliability, the proposed method can be an advantageous alternative to the traditional methodology for the quantitation of CoQ10 in human plasma with good accuracy and precision.     

微乳液相色谱法同时测定山楂叶提取物中4种黄酮成分

建立了一种新的微乳体系,用于微乳液相色谱同时分析山楂叶提取物中牡荆素鼠李糖苷、芦丁、牡荆素及金丝桃苷4种黄酮成分.通过对影响分离选择性的主要因素进行考察,得到最佳微乳体系的组成为: 1.0%(w/w) 聚氧乙烯月桂醇(Brij35)-1.1%(w/w)正丁醇-0.1%(w/w)正辛醇-0.3%三乙胺(V/V)(H_3PO_4调节至pH 2.5).在此微乳体系中,表面活性剂类型和浓度、油相种类、添加剂三乙胺、流动相的pH值对4种黄酮成分的分离起到了重要的作用.选择Venusil ASB C_(18)色谱柱(150 mm×4.6 mm, 5μm),流速为0.8 mL/min,检测波长为360 nm,柱温为35 ℃.结果显示,4种黄酮成分在27 min内达到基线分离,在0.95～140.8 mg/L范围内,4个黄酮成分的线性相关系数r≥0.9995,平均回收率98.6%～101.6%.本方法可应用于山楂叶提取物中4种主要黄酮成分的质量分析.