OASIS HLB固相萃取-高效液相色谱柱后衍生荧光检测花生中黄曲霉毒素B_1,B_2,G_1和G_2

测定黄曲霉毒素主要有薄层色谱法、柱前衍生液相色谱法[1]和柱后衍生液相色谱法[2]等。样品净化主要有液 液分配、C18键合柱[3]、免疫亲和柱[4]等方法。OASIS HLB是Wa ters公司近几年开发的亲水亲酯固相萃取柱,已用于腐败生物组织中吗啡的检测[5],它与传统的C18柱相比具有选择范围广、吸附能力强、重现性好、回收率高等特点,但尚未见应用于花生中黄曲霉毒素测定的报道。本文采用OASIS HLB固相小柱,建立了以碘作为柱后衍生试剂,反相液相色谱荧光检测花生中黄曲霉毒素B1,B2,G1,G2的分析方法。该法简单,快速,分离能力强,基体干扰…     

高压液相色谱分析DNS-[75Se]蛋氨酸

蛋氨酸属氨基酸类,无紫外吸收。[~(75)Se]蛋氨酸为其硒标记化合物,被广泛用作胰腺扫描、甲状腺扫描,某些肝肿瘤、恶性肿瘤的阳性扫描,恶性淋巴瘤的测定,胎盘机能的测定和人体内新陈代谢的研究等。 为提高分离效率,缩短分析时间,发展了柱前衍生化法。衍生化试剂1-二甲基胺萘-5-磺酰氯(DNS—C1)是示踪量测定氨基酸的最佳衍生化试剂,反应灵敏度比茚三酮高几个数量级。其衍生物制备迅速,重现性好,有紫外吸收,可利用高压液相色谱进行分离分析。     

高效液相色谱中的化学衍生法

色谱技术中的化学衍生法系指在色谱过程中用特殊的化学试剂(一般称为衍生化试剂或标记试剂)使样品成分转变相应的衍生物之后进行分离检测或进行检测的方法。近十年来,化学衍生法在高效液相色谱法中的应用受到重视,发展较快。在高效液相色谱法中,化学衍生化的目的为:1.将紫外一可见强吸收功能基团引入被检测对象或将其转变为荧光衍生物,以提高检测灵敏度;2.提高对分析样品的分离和选择性。     

毛细管电泳柱后衍生激光诱导荧光测定动物组织中卡那霉素类抗生素

采用毛细管电泳柱后衍生激光诱导荧光测定3种卡那霉素类抗生素。研究了在反向电渗流条件下HAc-NaAc缓冲液酸度和浓度对卡那霉素类抗生素分离的影响,研究了Na2B4O7缓冲体系和柱后衍生试剂萘二醛/2-巯基乙醇浓度对检测信号的影响。采用50 mmol/L HAc-NaAc(pH5.0) 0.5 mmol/L CTMAB溶液为分离缓冲液,样品在-15 kV下分离,与柱后衍生试剂1.0 mmol/L NDA 8.0 mmol/L 2-ME 35 mmol/LNa2B4O7(pH10.0)的30%(V/V)甲醇溶液反应,激发诱导荧光检测卡那霉素类抗生素检出限为3.6×10-5~5.2×10-5g/L;本方法用于动物组织中卡那霉素类抗生素残留检测,相对标准偏差小于7.2%;回收率为90.2%~95.3%(n=4)。     

高效液相色谱法对粉条中甲醛含量的快速检测

建立了Nash试剂柱前衍生高效液相色谱法快速测定土豆粉条样品中甲醛含量的分析方法.考察了衍生试剂、衍生反应条件及衍生物的稳定性.Nash试剂柱前衍生,产物经Agilent Zorbax Eclipse XDB-C18(4.6mm× 250 mm,5μm)柱分离,采用可变波长扫描紫外检测器(VWD)检测,检测波长412 ...     

花生油中游离脂肪酸的HPLC-FLD分析

采用柱前衍生-高效液相色谱荧光检测法(HPLC-FLD)分析了花生油中的游离脂肪酸.用荧光衍生试剂2-(11 H-苯[a]咔唑)乙基对甲苯磺酸酯(BCETS)作为柱前衍生化试剂对11种脂肪酸标准品(9种不饱和脂肪酸和棕榈酸、硬脂酸)进行衍生,经梯度洗脱实现了11种游离脂肪酸BCETS衍生物的完全分离,使用外标法定量,建...     

咔唑-9-乙基氯甲酸酯柱前衍生胺类化合物高效液相色谱分离

采用一种新的氯甲酸酯类荧光衍生试剂咔唑-9-乙基氯甲酸酯进行柱前衍生胺类化合物并通过荧光检测的方法进行高效液相色谱(HPLC)分析。衍生物的荧光激发和发射波长为λcr／λcrs=293/365nm。色谱柱：Hypersil BDS C18柱，柱温：35℃；流速：l mL/min；流动相A为水/乙腈(20／80，V／V)，流动相B为乙腈/水(95／5，V／V)。衍生试剂用量(mol)是胺类化合物总量的3～4倍时，衍生化产率最大且恒定。该方法具有检测灵敏度高，衍生化反应简单、快速、不受样品基质盐分的干扰，尤其适合天然生物样品，食品及饲料中的胺类化合物的分析。     

柱前衍生-高效液相色谱分离测定及质谱鉴定脂肪胺

采用新型荧光衍生试剂2-(2-苯基-1-氢-菲[9,10-d]咪唑)-乙酸(PPIA)进行柱前衍生,经荧光检测实现了脂肪胺的高效液相色谱(HPLC)分离测定及柱后质谱鉴定。60℃下在乙腈溶剂中用N-乙基-N′-[(3-二甲氨基)丙基]碳二亚胺盐酸盐(EDC)做缩合剂,衍生反应15min可获得稳定的荧光产物。脂肪胺衍生物荧光检测波长为380nm(激发波长为260nm)。在EclipseXDB-C8色谱柱上,采用梯度洗脱对12种脂肪胺衍生物进行了优化分离,测定了造纸厂废水、大鼠端脑和酸奶中脂肪胺的含量。经柱后在线质谱大气压化学电离源(APCISource)正离子模式实现了各种脂肪胺衍生物的质谱鉴定,借助对活性中间体的质谱解析确定了衍生反应的反应机理。该方法具有良好的重现性和回收率,多数脂肪胺的线性回归系数大于0.9996;检出限为3.1~18fmol(S/N=3∶1)。     

烟草及烟用香精香料中氨基酸检测方法研究进展

烟草及烟用香精香料中氨基酸的含量对烟草品质有着直接而重要的影响,因此有必要进行准确定性定量分析.氨基酸检测方法可分为直接检测法和间接检测法两大类,间接检测法又可分为柱前衍生法和柱后衍生法.分析了每种方法的优缺点以及常用的衍生化试剂,以期为进行氨基酸分析的研究者提供参考.     

柱前衍生-超高效液相色谱-电化学检测法测定牙膏中氨甲环酸

约1g牙膏样品用水50mL超声萃取30min后再离心10min,然后取上清液加入等体积的衍生试剂溶液[含有150mg·L~(-1)邻苯二甲醛(OPA)和1.3g·L~(-1)亚硫酸钠],在室温下反应5min,完成对氨甲环酸的衍生化,衍生化后的样品溶液用超高效液相色谱-电化学检测器(UPLCECD)分析。采用Waters ACQUITY UPLC BEH C18色谱柱作为固定相,以体积比为2∶8的乙腈-30mmol·L~(-1)乙酸铵缓冲溶液(pH 3.6)为流动相进行等度洗脱。结果显示:氨甲环酸的质量浓度在0.495～19.800mg·L~(-1)内与其对应的色谱峰面积呈线性关系,检出限(3S/N)为0.18μg·g~(-1)。对牙膏样品进行了加标回收试验,回收率为98.6%,测定值的相对标准偏差(n=6)为2.4%。氨甲环酸衍生产物在12h内保持稳定(衍生产物峰面积降低了不到5%)。方法用于6个牙膏样品的分析,在已知添加的牙膏样品中检出了氨甲环酸,其质量分数为0.23mg·g~(-1)。     

Liquid‐Chromatography Quantitative Analysis of 20 Amino Acids after Derivatization with FMOC‐Cl and Its Application to Different Origin Radix isatidis

We developed a simple, rapid and reliable method for determination of 20 common amino acids based on derivatization with 9‐fluorenylmethyl chloroformate (FMOC‐Cl) and RP‐LC/UV, this method was first introduced into quantitative analysis of amino acids. The amino groups of amino acids were trapped with FMOC‐Cl to form amino acid‐FMOC‐Cl adducts which can be suitable for LC‐UV. Chromatographic separation was performed on a C₁₈ column with a mobile phase gradient consisting of acetonitrile and sodium acetate solution. This method was shown to be sensitive for 20 common amino acids. In the intra‐day precisions assay, the range of RSDs was 3.21‐7.67% with accuracies of 92.34‐102.51%; for the inter‐day precisions assay, the range of RSDs was 5.82‐9.19% with accuracies of 90.25‐100.63%. The results also indicated that solutions of amino acids‐FMOC‐Cl can be kept at room temperature for at least 24 h without showing significant losses in the quantified values. The validated method was successfully applied to the determination of major four kinds of amino acids in R. isatidis samples (Arg, Pro, Met and Val). The total content of amino acids in different origin R. isatidis was 13.32‐19.16 mg/g. The differences between R. isatidis samples were large using HCA.     

High-performance liquid chromatographic determination of memantine hydrochloride in rat plasma using sensitive fluorometric derivatization

In this study, we investigated a simple, sensitive and reliable liquid chromatography‐fluorescence detection method for the determination of memantine hydrochloride in rat plasma which was based on derivatization with 9‐fluorenylmethyl chloroformate (FMOC‐Cl). For the first time, FMOC‐Cl was introduced into derivatization of memantine hydrochloride in rat plasma. The amino groups of memantine hydrochloride and amantadine hydrochloride (internal standard) were trapped with FMOC‐Cl to form memantine hydrochloride‐FMOC‐Cl and amantadine hydrochloride‐FMOC‐Cl compositions, which can be very compatible for LC‐FLD. Precipitation of plasma proteins by acetonitrile was followed by vortex mixing and centrifugation. Chromatographic separation was performed on a C₁₈ column (DIAMONSIL 150×4.6 mm, id 5 μm) with a mobile phase consisting of acetonitrile and water at a flow rate of 1.0 mL/min. The retention times of memantine hydrochloride‐FMOC‐Cl and amantadine hydrochloride‐FMOC‐Cl compositions were 23.69 and 40.27 min, respectively. Optimal conditions for the derivatization of memantine hydrochloride were also described. The limit of quantification (LOQ) was 25 ng/mL for memantine hydrochloride in plasma, the linear range was 0.025–5.0 μg/mL in plasma with a correlation coefficient (r) of 0.9999. The relative standard deviations (RSDs) of intra‐day and inter‐day assays were 4.46–12.19 and 5.23–11.50%, respectively. The validated method was successfully applied to the determination of memantine hydrochloride in rat plasma samples.     

Effect of halides on the TLC resolution of amino acids below their isoelectric points

TLC of a fifteen component mixture of amino acids has been carried out in two ways; firstly, the amino acids were treated with halides below their isoelectric points and chromatographed on plain silica plates, and secondly the amino acids in their cationic forms were chromatographed on silica plates impregnated with halides, keeping the same solvent system. The resolution is considered to be affected by hydrophobic interactions between silica gel and amino acid molecule and by the polarity and the flow of the mobile phase. The method provides resolution of 10–11 amino acids from the fifteen component mixture.     

Fast Analysis of Free Amino Acids in Tobacco by HPLC with Fluorescence Detection and Automated Derivatization

A fast, simple, and sensitive HPLC method for the determination of free amino acids in tobacco was described. A fully automated sample processor performed precolumn derivatization of both primary and secondary amino acids with o‐phthalaldehyde/3‐mercaptopropionic acid and 9‐fluorenylmethyl chloroformate (FMOC‐Cl), respectively. All reactions were fully automated by means of an injector programme and accomplished in 10 min. Sample preparation consisted of a single step of extraction with 0.1 mol/L HCl at ambient temperature (assisted by sonication) in 30 min, followed by filtration of an aliquot and derivatization. By optimization of sample preparation and HPLC conditions, separation of 20 amino acids in 30 min was achieved. Detection limits ranged from 0.50 to 1.40 μg/g; coefficients of variation ranged from 1.8% to 3.9%; recoveries ranged from 84.6% to 108.5%. The method was applied to the analysis of amino acids contents of tobacco leaves in different varieties and flue‐curing period.     

Quantitation of amino acids in plasma by high performance liquid chromatography: Simultaneous deproteinization and derivatization with 9-fluorenylmethyloxycarbonyl chloride

This paper, as a novelty to this field, presents the deproteinization and derivatization of plasma's free amino acids (PFAAs), simultaneously, in a single step, with the acetonitrile (ACN) containing 9-fluorenylmethyloxycarbonyl chloride (FMOC) reagent. Deproteinization and derivatization, were studied with 22 amino acids, applying photodiode array (DAD) and fluorescence (FL) detection, simultaneously. Model investigations have been carried out as a function of the FMOC concentration, reaction time and reaction conditions: with standard solutions, with human plasma samples in its initial condition and fortified with standard amino acids (excluding tryptophan because it co-elutes with the hydrolyzed FMOC). Reproducibilities of 22 amino acids, including both histidine and tyrosine derivatives, obtained under optimum derivatization conditions are presented (at 3.0 mM FMOC concentration, at pH 9; derivatization time = 20 min), and characterized with the relative standard deviation percentages of their responses (≤4.4%, RSD). Quantitation limit (LOQ) of amino acid FMOC derivatives proved to be 2.5 pmol, except for cystine, ornithine (5 pmol) and for the total of tyrosines (N-FMOC-tyrosine and N,O-FMOC-tyrosine 10 pmol).     

Amino acid analysis by high-performance liquid chromatography with methanesulfonic acid hydrolysis and 9-fluorenylmethylchloroformate derivatization

Experiments were undertaken to verify a method for complete amino acid analysis of plant and animal tissues and waste products from a single hydrolysis and high-performance liquid chromatographic run. Using methanesulfonic acid, hydrolysis of cytochrome c at 115 degrees C for 22 h yielded recoveries equal to or higher than hydrolysis at 115 degrees C for 70 h or at 150 degrees C for 22 h. Triple evacuation of the hydrolysis tube alternated with nitrogen flush gave recovery improvements over single evacuation. Refrigerated storage of samples under vacuum for up to 4 days between hydrolysis and further analysis was not different from immediate analysis. However, recoveries of several amino acids were reduced by refrigerated storage in air. Recoveries of individual amino acids were determined by hydrolysis of biological samples with and without added cytochrome c. Although recoveries from biological samples were lower for several amino acids, precision was sufficient to allow quantitation after correction for incomplete recoveries. Derivatization with 9-fluorenylmethylchloroformate (FMOC) was chosen because derivatives are formed with both primary and secondary amino acids, derivatives are quite stable, and detection may be either UV absorbance or fluorescence. Derivative yield is sensitive to the pH of the reaction mixture. A pH of 8.0 gave reproducible derivative yield for all physiological amino acids. Solvent extraction of excess FMOC, when compared to addition of amantadine to react with excess FMOC, gave both higher recoveries and greater precision. Following derivatization, samples could be kept at 4 degrees C for at least 24 h before high-performance liquid chromatographic analysis without loss of response. Derivative yield and detector response were constant across a wide range of molar ratio of FMOC to total amino acids. Gradient elution was required to separate FMOC derivatives on a reversed-phase column. The capability of the pumping system to produce exponential gradients permitted rapid and easy fine-tuning of the gradient.     

Amino acids: aspects of impurity profiling by means of CE

Quality control of active pharmaceutical ingredients (API) is commonly performed by means of HPLC. However, CE offers a suitable alternative, especially for the analysis of easily chargeable substances, i.e., amino acids. The article reviews, on the one hand, CE methods developed for impurity profiling of synthesized amino acid analogs. However, nowadays, production of amino acids/peptides is dominated by fermentation. Therefore, on the other hand, CE methods for the analysis of amino acids and small peptides are reported. The results of CE analysis of glutathione samples according to the monograph in the European Pharmacopoeia (Ph. Eur.) 5.7 and amino acid samples after derivatization with 9-fluorenylmethyl chloroformate (FMOC) and 3-(4-carboxybenzoyl)quinoline-2-carboxaldehyde (CBQCA) may pave the way for impurity profiling of fermentatively produced API by means of CE.     

Determination of orthophthalaldehyde in air using 2,4-dinitrophenylhydrazine-impregnated silica cartridge and high-performance liquid chromatography

A new method is described for the determination of orthophthalaldehyde in air which is used for the disinfection of various instruments (e.g. endoscopes) in hospital. Orthophthalaldehyde in air was collected with a silica gel cartridge impregnated with acidified 2,4-dinitrophenylhydrazine (DNPH-cartridge) and derivatives were analyzed by high-performance liquid chromatography (HPLC). In this study, the derivatization was examined by comparing the process with three phthalaldehyde isomers (ortho-, iso- and tere-). In the case of iso- and tere-phthalaldehyde, derivatives synthesized with excess of aldehyde consisted mainly of mono-derivatives, and derivatives synthesized with excess of DNPH consisted mainly of bis-derivative. In the case of orthophthalaldehyde, derivative consisted of only bis-derivative and mono-derivative was never observed under any conditions. Orthophthalaldehyde was completely retained by the DNPH-cartridge during air sampling, however, the derivatization reaction was incomplete and unreacted orthophthalaldehyde was flushed from the cartridge during the subsequent solvent extraction process. Unreacted orthophthalaldehyde and DNPH reacted again in the extraction solvent solution. Immediately after the solvent extraction, both mono- and bis-DNPhydrazone derivatives of orthophthalaldehyde were present in the solution. However, over time, the mono-derivative decreased and bis-derivative increased until only the bis-derivative was left allowing accurate determination of the orthophthalaldehyde concentration. The transformation of mono-derivative to bis-derivative was faster in polar aprotic solvents such as acetonitrile, dimethyl sulfoxide and ethyl acetate. Transformation was found to occur most quickly in acetonitrile solvent and was completed in 4 h in this case. It was possible to measure orthophthalaldehyde in air as bis-derivative using a DNPH impregnated silica cartridge and HPLC analysis.     

Analysis of amino acids in individual human erythrocytes by capillary electrophoresis with electroporation for intracellular derivatization and laser-induced fluorescence detection

A method for monitoring amino acids in single erythrocytes is described. For intracellular derivatization, reagent fluorescein isothiocyanate (FITC) was introduced into living cells by electroporation. For an 8 microm erythrocyte, the analytes were diluted by a factor of only 1.6. After completion of the derivatization reaction, a single cell was injected into the separation capillary tip and lysed there. The derivatized amino acids were separated by capillary electrophoresis, followed by laser-induced fluorescence detection. Nine amino acids were quantitatively determined, with amounts of amino acids ranging from 3.8-32 amol/single cell.