同位素稀释-气相色谱-质谱法测定食用植物油中总氯丙醇脂肪酸酯

建立了食用植物油中总氯丙醇脂肪酸酯(氯丙醇酯)的同位素稀释-气相色谱-质谱(GC-MS)检测方法。样品经甲醇钠-甲醇溶液水解,硅藻土小柱净化,七氟丁酰咪唑(HFBI)衍生后,GC-MS 检测,同位素内标法定量。3-MCPD 酯、2-MCPD 酯、1,3-DCP 酯和2,3-DCP 酯在0.050~2.000 mg/ L 浓度范围内,均呈良好线性相关,相关系数(R)均大于0.9995。3-MCPD 酯、2-MCPD 酯、1,3-DCP 酯和2,3-DCP 酯的检出限分别为0.015,0.015,0.030和0.030 mg/ kg,定量限分别为0.050,0.050,0.100和0.100 mg/ kg。以空白特级初榨橄榄油为空白基质的加标回收实验的平均回收率为87.0%~110.5%,相对标准偏差(RSD)均小于10.1%。在74份食用植物油样品中,3-MCPD 酯、2-MCPD 酯和1,3-DCP 酯的检出率分别为94.6%,63.5%和5.4%,未检出2,3-DCP 酯;3-MCPD 酯、2-MCPD 酯和1,3-DCP 酯的含量分别在未检出(ND)~10.646 mg/ kg、ND ~3.617 mg/ kg 和ND ~0.089 mg/ kg 之间。本方法简便、准确、可靠,适用于食用植物油中总氯丙醇酯的测定。     

超高效合相色谱法同时测定复合维生素片中11种脂溶性维生素及其衍生物

建立了超高效合相色谱法(Ultra performance convergence chromatography,UPC2)分离和测定复合维生素片中11种脂溶性维生素(A,D,E,K)及其衍生物的方法。超高效合相色谱(UPC2)技术集合超临界流体色谱(Supercritical fluid chromatography,SFC)和超高效液相色谱(Ultra performance liquid chromatography,UPLCTM)的技术优点,流动相以CO2为主体,乙腈为助溶剂梯度洗脱。选用Waters Acquity UPC2HSS C18SB色谱柱(100 mm×3.0 mm 1.8μm),流速1 m L/min,检测波长为284 nm。方法检出限在1.5~2.0 mg/L之间;VK1,VK2,VK3和VD3的线性范围分别为3~300 mg/L;VA、VA棕榈酸酯、VA甲酸、VE、VE醋酸酯、VE琥珀酸酯和VD2的线性范围分别为5~300 mg/L;加标回收率范围为97.31%~98.76%;相对标准偏差为0.41%~0.96%,可以满足复合维生素片中11种脂溶性维生素(A,D,E,K)及其衍生物的方法要求。     

双波长分光光度法同时测定水样中的Cr(Ⅲ)和Cr(Ⅵ)

以EDTA为显色剂,在pH 3.5~4.0,75℃水浴加热条件下,用双波长分光光度法同时测定水中Cr(Ⅲ)和Cr(Ⅵ)。选择测定Cr(Ⅵ)的波长对为352nm和441 nm,测定Cr(Ⅲ)的波长为542 nm,Cr(Ⅵ)的线性范围和检出限分别为0~120 mg/L和0.025 mg/L;Cr(Ⅲ)线性范围和检出限分别为0~140 mg/L和0.007 mg/L。Cr(Ⅵ)和Cr(Ⅲ)加标回收率分别为96.4%~100.4%和99.8%~104.5%。     

固相萃取-阴离子交换色谱法测定硝酸异辛酯合成后残留的混酸含量

建立了一种固相萃取-阴离子交换色谱-抑制型电导检测的分析方法,同时测定合成硝酸异辛酯(柴油十六烷值改进剂)反应后残留的混酸(硝酸和硫酸)的含量。样品经过Bond Elut C18OH固相萃取小柱萃取净化后,以1.0m L/min的流速,经Shim-pack IC-SA2阴离子交换分析柱(4.0 mm i.d×250mm,9μm)分离,淋洗液为1.8 mmol/L Na2CO3-1.7 mmol/L Na HCO3混合液,进行等度洗脱,并用外标法进行定量分析。硝酸和硫酸分别在0.3~9 mg/L和12~120 mg/L范围内呈良好的线性关系,相关系数分别为0.999和0.996;加标回收率分别为90.0%~101.43%和94.25%~102.4%,检出限为0.01 mg/L和0.05 mg/L,相对标准偏差RSD(n=6)小于3.0%。     

阿德福韦酯及其有关物质的胶束电动毛细管色谱法快速测定

采用胶束电动毛细管色谱法对阿德福韦酯及其有关物质进行了快速分离与测定,并对电泳条件进行了优化.在优化条件下,阿德福韦酯及其有关物质在12 min内得到良好的分离,阿德福韦与阿德福韦酯在质量浓度分别为6.28×10-2～4.02 g·L-1与6.19×10-2～3.96 g·L-1的范围内与峰面积呈良好的线性关系,加标回收率分别为100%～101%和98%～101%,检出限分别为0.3、0.5 mg·L-1.该方法简单、快速,适用于阿德福韦酯及其有关物质的常规检查和该药的质量控制.     

衍生化-气相色谱-质谱法测定染整助剂中的乙二胺四乙酸盐和二乙烯三胺五乙酸盐

建立了乙二胺四乙酸盐(EDTA)和二乙烯三胺五乙酸盐(DTPA)衍生化成乙基酯的前处理方法以及气相色谱-质谱法测定乙基酯的方法。样品经甲酸酸化后,与乙醇发生酯化反应生成乙基酯,由正己烷提取,选择离子模式下由优化好的气相色谱-质谱进行定性定量分析。EDTA和DTPA质量浓度分别在0.2~20.0 mg/L和0.5~50.0 mg/L范围内线性关系良好,相关系数均不小于0.9991,两种不同阴性样品的3个不同浓度添加水平的平均回收率在91.6%~94.9%之间,相对标准偏差均不大于5.2%,EDTA和DTPA检出限分别为0.0609 mg/kg和0.145 mg/kg,定量限分别为0.194 mg/kg和0.476 mg/kg。方法能够满足染整助剂中EDT A和DT PA定性确证和准确定量的要求。     

醌亚胺类碱性染料荧光猝灭法测定肝素钠

建立了醌亚胺类碱性染料(藏红O、中性红、耐尔蓝A)荧光猝灭法测定肝素钠的方法。方法的线性范围和检出限分别为0.008~0.8 mg/L,3μg/L(藏红O体系);0.06~2.0 mg/L,40μg/L(中性红体系);0.05~1.0 mg/L,20μg/L(耐尔蓝A体系),其中以藏红O体系最为灵敏。以藏红O体系为例研究了共存物质的影响,方法已用于肝素钠注射液效价的测定。     

高效液相色谱-二极管阵列检测法测定L-丙氨酸与L-氨基丙醇

建立了柱前衍生同时测定L丙-氨酸、L氨-基丙醇的高效液相色谱方法。色谱条件为:Shim-pack VP-ODS柱(150 mm×4.6 mm.ID.,5μm);二极管阵列检测器;流动相为甲醇-磷酸盐缓冲溶液(NaH2PO4浓度为0.02 mol/L,pH 4.00 H3PO4调节)(体积比为30∶70),流速为0.5 mL/m in,检测波长为222 nm,柱温为30℃。L丙-氨酸与L氨-基丙醇的线性范围分别为2.30~178 mg/L和9.3~8690 mg/L;检出限分别为1.1 mg/L和1.6 mg/L;日内、日间测定的相对标准偏差(RSD)分别为0.22%、0.46%和0.02%、0.03%。     

抗氧化剂没食子酸丙酯合成纳米银及其应用

在十六烷基三甲基溴化铵(CTAB)存在下, 硝酸银与没食子酸丙酯在碱性介质中发生还原反应, 制得纳米银; 考察了反应时间、 氢氧化钠浓度、 反应温度以及PG/Ag⁺浓度比等条件对合成纳米银粒子的影响. 利用扫描电子显微镜对纳米银颗粒形貌和尺寸进行了表征, 结果表明获得了分散性良好的球形粒子. 实验中还发现在还原银离子制备纳米银过程中会产生强烈的表面等离子共振峰, 用紫外-可见光谱监测制备过程得到的纳米银紫外吸收带范围为400~450 nm, 最大吸收波长为420 nm, 光谱强度与抗氧化剂的浓度成正比. 将纳米银的这一特性用于定量测定没食子酸丙酯(PG)、 二丁基羟基甲苯(BHT)、 叔丁基对羟基茴香醚(BHA)和叔丁基对苯二酚(TBHQ)等抗氧化剂, 所得检出限分别为0.0752, 0.1242, 0.0693和0.0701 mg/L, 线性范围分别为0.2~1.8, 0.2~3.4, 0.2~3.4和0.2~3.0 mg/L.     

电堆集富集非水毛细管电泳同时测定水杨酸、肉桂酸、阿魏酸和香草酸

建立了同时分离测定水杨酸、肉桂酸、阿魏酸和香草酸的电堆集富集-非水毛细管电泳(NACE)的新方法。运行缓冲溶液为40mmol/L乙酸钠-2.5mmol/L氢氧化钠甲醇溶液,电压-25kV,在225nm波长下紫外检测。对电压、乙酸钠浓度、氢氧化钠浓度、进样时间、样品溶液等因素对电堆集及分离的影响做了系统的研究。水杨酸、肉桂酸、阿魏酸和香草酸分别在1.4~28mg/L、0.40~8.0mg/L、0.7~18mg/L和0.7~30mg/L范围内线性关系良好(r=0.9999、r=0.9997、r=0.9994、r=0.9997);回收率分别为95.8~99.6%、96.2~98·2%、95.7~105%和98.9~103%,基于3倍信噪比(S/N=3),4种有机酸的检出限分别为0.069、0.051、0.107和0.089mg/L。     

毛细管电泳法快速检测消毒剂中的醋酸氯己定

建立了消毒剂中活性成分醋酸氯己定(又名:醋酸洗必泰)的毛细管电泳快速检测法。采用15 mmol/L磷酸盐-乙腈( 体积比为60∶40)缓冲体系,将醋酸氯己定在50 cm×75 μm i.d.的石英毛细管柱中进行电泳分离,电泳电压为15 kV,检 测波长为254 nm。同时,对毛细管电泳分析醋酸氯己定的条件(如缓冲液的种类、pH值、浓度及电泳电压等)进行了优化 。用该方法对消毒剂样品进行测定,在4 min内可完成分析。醋酸氯己定在质量浓度为0.01～0.10 g/L时线性良好,检测 限为0.004 mg/L,吸光度值的相对标准偏差为3.97%,迁移时间的相对标准偏差为2.99%,样品加标回收率为91.4%～116.6%。将该方法 与高效液相色谱法进行比较,两种方法测定结果的相对误差≤4%。所建立的检测醋酸氯己定含量的毛细管区带电泳法简单 、快速,适用于消毒剂样品的测定。     

离子对色谱法同时分离测定吡啶及咪唑离子液体阳离子

建立了用紫外检测的反相离子对色谱梯度淋洗同时分离测定4种吡啶离子液体阳离子和5种咪唑离子液体阳离子的方法。实验采用ZORBAX Eclipse XDB-C18反相色谱柱,以离子对试剂水溶液(用柠檬酸调节pH值)+乙腈为流动相,考察了离子对试剂种类和浓度、乙腈浓度和色谱柱温度对保留的影响,探讨了相关保留规律,确定最佳色谱条件为:流速1.0 mL/min、柱温30℃,以1.0 mmol/L庚烷磺酸钠水溶液(pH 4.0)-乙腈为淋洗液进行梯度洗脱。在此条件下,4种吡啶阳离子和5种咪唑阳离子在15 min内达到基线分离。检出限(S/N=3)为0.31～0.54 mg/L,峰面积的相对标准偏差为0.10%～0.75%。将该方法用于实验室合成的离子液体样品分析,加标回收率为94%～98%。该方法准确、可靠,具有较好的实用性。     

Determination of amino acid neurotransmitters in rat hippocampi by HPLC‐UV using NBD‐F as a derivative

A simple, rapid and accurate high‐performance liquid chromatography method with ultraviolet–visible detection was developed for the determination of five amino acid neurotransmitters – aspartate, glutamic acid, glycine, taurine and γ‐aminobutyric acid – in rat hippocampi with pre‐column derivatization with 4‐fluoro‐7‐nitrobenzofurazan. Several conditions which influenced derivatization and separation, such as pH, temperature, acetonitrile percentage mobile phase and flow rate, were optimized to obtain a suitable protocol for amino acids quantification in samples. The separation of the five neurotransmitter derivatives was performed on a C₁₈ column using a mobile phase consisting of phosphate buffer (0.02 mol/L, pH 6.0)–acetonitrile (84:16, v/v) at a flow rate of 1.0 mL/min with the column temperature at 30°C. The detection wavelength was 472 nm. Without gradient elution, the five neurotransmitter derivatives were completely separated within 15 min. The linear relation was good in the range from 0.50 to 500 µmol/L, and the correlation coefficients were ≥0.999. Intra‐day precision was between 1.8 and 3.2%, and inter‐day precision was between 2.4 and 4.7%. The limits of detection (signal‐to‐noise ratio 3) were from 0.02 to 0.15 µmol/L. The established method was used to determine amino acid neurotransmitters in rat hippocampi with satisfactory recoveries varying from 94.9 to 105.2%. Copyright © 2013 John Wiley & Sons, Ltd.     

New approach for determination of the degradation products of fenspiride hydrochloride found in oral liquid formulations

Fenspiride hydrochloride (FNS) is used in treating chronic inflammatory diseases, most commonly as a liquid oral solution. FNS produces degradation products along with fenspiride N‐oxide (FNO) and 1‐phenylethyl‐4‐hydroxy‐4‐aminomethyl piperidine hydrochloride (PHAP). We aimed to develop and validate a chromatographic method in order to identify the main degradation products in the presence of other compounds from a liquid preparation. The method used a dual gradient using two buffer solutions: the first with pH 4.5 (buffer 1, pH 4.5–MeOH 90:10%, v/v) and the second with pH 2.9 (buffer 2, pH 2.9–acetronitrile–methanol, 65:15:10%, v/v/v). As mentioned, there was a modification of the organic mixture, starting with 10% methanol and ending with a mixture of acetonitrile–methanol (15:10%, v/v). The flow‐rate was 1.5 mL/min. According to the elution program, experimental conditions started with 100% solution S1, which decreased to 0% and, simultaneously, solution S2 increased to 100% during the first 10 min and was maintained for a further 5 min. After 15 min, initial conditions were re‐established. The linearity interval was 0.5–2 μg/mL and the minimum correlation coefficient was 0.999. The recovery factor was 100.47–103.17% and the limit of quantification was 0.19–0.332 μg/mL. Intra‐day maximum precision was 4.08% for FNS and 2.65% for PHAP. This double‐gradient mobile phase produced good specificity in relation to the degradation products of FNS and other constituents of the oral liquid formulation. Forced degradation studies revealed other related substances that were confirmed in mass balance analyses. Degradation products were confirmed in acidic, basic and oxidative media.     

Stress degradation studies and kinetic determinations of duloxetine enteric-coated pellets by HPLC

A stability-indicating HPLC assay method was developed for the quantitative determination of duloxetine (DLX) in a pharmaceutical dosage form in the presence of its degradation products, and kinetic determinations were evaluated in acid conditions and UV-C radiation exposure. Chromatographic separation was achieved by use of an ACE C18 column (250 x 4.0 mm id, 5 microm particle size). The mobile phase was prepared by mixing aqueous 50 mM potassium phosphate buffer (pH 6.0 containing 0.3% triethylamine) and acetonitrile (60 + 40, v/v). DLX was rapidly degraded in an acid medium and in the presence of hydrogen peroxide and UV-C radiation; it was more stable in alkaline medium. The described method was linear over a range of 4.0-14.0 microg/mL for determination of DLX (r = 0.9998). The precision was demonstrated by the RSD of intraday (0.79-1.07%) and interday (0.85%) studies. The mean recovery was found to be 100.56%. The acid degradation of DLX in 0.1 M HCI solution showed an apparent zero-order kinetics (k = 0.177 microg/mL/min), and the photodegradation demonstrated an apparent first-order kinetics (k = 0.082 microg/mL/min). The developed method was found to be simple, specific, robust, linear, precise, and accurate for the determination of DLX in enteric-coated pellets.     

Identification and structural characterization of major degradation products of tapentadol by using liquid chromatography–tandem mass spectrometry

Tapentadol, a centrally acting analgesic was subjected to hydrolysis (acidic, alkaline, and neutral), oxidation, photolysis, humidity, and thermal stress conditions as per International Conference on Harmonization prescribed guidelines. Tapentadol was found susceptible to oxidative stress that produced two major degradation products DP-I and DP-II. However, it was stable to hydrolysis, photolysis, and thermal stress conditions. A simple, sensitive, and accurate high-performance liquid chromatography stability-indicating assay method (liquid chromatography–mass spectrometer compatible) was developed and validated for identification and characterization of stressed degradation products of Tapentadol. The chromatographic separation of the drug and its degradation products were achieved on Inertsil ODS, C18 (250 × 4.6 mm, i.d., 5 µm) column using a 12.5 mM aqueous ammonium acetate buffer (with 0.2% triethyl amine and final pH of buffer was adjusted to 3.60 with glacial acetic acid): acetonitrile (75:25, v/v) as a mobile phase. The degradation products were characterized by liquid chromatography mass spectrometry and subsequently its fragmentation pathway as well as plausible mechanism for generation of degradation products was also proposed. The stability indicating high-performance liquid chromatographic method was validated with respect to linearity, precision, and accuracy.     

柱前衍生化高效液相色谱-荧光检测法测定桑叶中的1-脱氧野尻霉素

采用柱前衍生化高效液相色谱-荧光检测法测定了桑叶中的1-脱氧野尻霉素(DNJ)。用0.05 mol/L HCl提取桑叶中的DNJ,采用6-氨基喹啉基-N-羟基琥珀酰亚氨基甲酸酯(AQC)试剂在pH 8.5硼酸盐缓冲液下对DNJ进行衍生化,以0.02 mol/L磷酸二氢钾缓冲液(pH 5.0)-乙腈(体积比为85∶15)为流动相,利用C18色谱柱(5 μm,250 mm×4.6 mm)分离,在激发波长为250 nm、发射波长为395 nm条件下进行荧光检测,DNJ的AQC衍生物与衍生化试剂的水解产物分离良好。方法的线性范围为0.5～25 mg/L,检出限为0.02 mg/L（S/N=3）。实验测得桑叶中DNJ含量为0.12%;回收率为96.1%～98.6%。     

高效液相色谱法分析环境样品中的苯基胂化合物

二苯氯胂和二苯氰胂是刺激性毒剂,在环境中易于降解,其产物苯胂酸、苯胂氧、二苯胂酸、氧联双二苯胂和三苯胂比较稳定,对环境危害大。建立了同时测定这5种含胂产物的反相高效液相色谱方法,选择了最佳色谱条件,提供了各组分的紫外光谱图。5种化合物的线性范围分别为8~30,5~40,20~4000,120~8000,1~60 mg/L,检测限分别为0.1,0.1,0.2,10,0.1 mg/L。对实际环境样品进行了分析,结果较好。     

鼠脑组织中6-羟基-1-甲基-1,2,3,4-四氢-β-咔啉及其相关生物胺的高效液相色谱-电化学检测

建立了大鼠脑组织中6-羟基-1-甲基-1,2,3,4-四氢-β-咔啉(6-OH-MTHβC)、5-羟色胺(5-HT)和5-羟吲哚乙酸(5-HIAA)含量的高效液相色谱-库仑阵列电化学检测(HPLC-ECD)方法。采用的色谱柱为DiscoveryHS F5柱(250 mm×4.6 mm,5 μm),流动相为缓冲液（40 mmol/L柠檬酸+20 mmol/L磷酸氢二钠+0.3 mmol/L乙二胺四乙酸二钠,pH 4.0）-甲醇（体积比为78∶22）混合液,流速为1 mL/min。6-OH-MTHβC、5-HT、5-HIAA在1.0～500.0 μg/L范围内线性关系良好(r>0.9992),检出限分别为0.56,0.26,0.53 μg/L,日内和日间精密度(以相对标准偏差表示)均低于6.1%,回收率分别为87.1%～98.2%,87.0%～95.3%,90.1%～97.7%。用该方法检测新生7 d的SD胎鼠脑内6-OH-MTHβC及5-HT、5-HIAA的含量,发现SD胎鼠在急性酒精中毒8 h后6-OH-MTHβC显著上升(P<0.05);而5-HT和5-HIAA的含量有所下降,但无显著性差异。该法简便、稳定、灵敏度高,适用于测定鼠脑组织中6-OH-MTHβC和5-HT,5-HIAA含量的相关研究。     

Determination of glucosamine and carisoprodol in pharmaceutical formulations by LC with pre-column derivatization and UV detection

A simple and reliable precolumn derivatization liquid chromatography method with ultraviolet detection has been developed and validated for the analysis of glucosamine (GS) in various dietary supplement formulations and raw materials. Additionally, the proposed method was used for analysis of carisoprodol (CR) found in ternary mixture with paracetamol (PR) and caffeine (CF). The linearity ranges were 1-100 μg/mL for GS, 1-150 μg/mL for CR, PR and CF. Derivatization was used with 1,2-naphthoquinone-4-sulphonic acid sodium salt in the presence of borate buffer. Chromatographic separation of GS-naphthoquinone derivative was achieved by using a mixture of acetonitrile and water (pH 7.3 adjusted with 0.1 M NaOH) in the ratio 10:90, v/v and flow-rate of 1.0 mL/min. UV detection was carried out at 280 nm. For PR, CF, and CR-naphthoquinone derivative, the chromatographic separation was achieved by using mixture of acetonitrile and 20 mM KH(2)PO(4) (pH 3.0 adjusted with phosphoric acid) in the ratio 20:80, v/v and flow-rate of 1.0 mL/min. UV detection was carried out at 275 nm. The limits of detection were 37.2, 35.9, 30.4 and 40.0 ng/mL for GS, CR, PR and CF, respectively.