反相高效液相色谱法测定血清中γ-氨基丁酸

建立一种高灵敏度的氯甲酸芴甲酯柱前衍生荧光检测反相高效液相色谱法测定血清中γ-氨基丁酸的方法.内标为己氨酸, 固定相为Shim-Pack CLC-ODS(M), 4.6 mm×150 mm, 填充料为5μm; 流动相采用二元梯度洗脱, A相为0.05 mol/L醋酸钠缓冲液∶水∶四氢呋喃∶冰乙酸(250∶100∶15∶2.2), B相为乙腈∶甲醇(4∶1).系统研究了pH值、反应时间、离子强度及衍生化试剂用量对衍生化反应的影响, 确定最佳反应条件和最佳色谱条件.方法的精密度为批内变异系数＜4.6%,批间变异系数＜6.1%;最低检出限(信噪比＝2)为3.1 nmol/L;线性范围为50～1000 nmol/L, γ²＝0.9992;平均回收率为97.1%.     

不同产地滇重楼须根中氨基酸类成分的UPLC分析与评价

建立柱前衍生-超高效液相色谱法测定滇重楼须根中15种氨基酸含量,对不同产地样品进行分析评价。采用UPLC-PDA仪器,使用ACQUITY UPLC BEH C_(18)色谱柱(2.1 mm×150 mm,1.7μm),流动相A为0.1 mol/L乙酸钠溶液(冰醋酸调节pH=6.5)-乙腈(97∶3),B为乙腈-水(4∶1),梯度洗脱,检测波长254 nm,流速0.2 mL/min。滇重楼须根中检出15种氨基酸线性关系良好(r≥0.999 7),平均回收率RSD均小于3.00%。各产地均以天门冬氨酸和谷氨酸含量为最高,栽培滇重楼须根氨基酸平均含量高于野生品。本研究建立了分析评价滇重楼须根中氨基酸类成分的方法,为滇重楼须根的资源开发与利用提供科学依据。     

柱前衍生化HPLC同时测定霍山石斛中13种游离氨基酸含量

为建立柱前衍生化HPLC同时测定霍山石斛中13种游离氨基酸的方法。采用Waters XBridge C_(18)色谱柱(250 mm×4. 6 mm,5μm);流动相为0. 1 mol/L醋酸钠缓冲液-乙腈∶水(4∶1),梯度洗脱;流速1. 0 mL/min,柱温35℃;检测波长254 nm。在该色谱条件下霍山石斛中13种游离氨基酸分离较好,平均加样回收率为92. 7%~104. 3%,RSD 2. 5%。该方法简便、准确、重现性好,适用于霍山石斛中13种游离氨基酸的同时测定。     

伊枯草菌素A发酵过程中游离氨基酸的HPLC分析

建立一种快速、高效测定游离氨基酸含量的异硫氰酸苯酯(PITC)柱前衍生高效液相色谱法,并利用此方法分析检测iturin A发酵过程中游离氨基酸的动态变化。以异硫氰酸苯酯(PITC)为衍生化试剂,采用Venusil-AA(4.6 mm×250 mm,5μm)氨基酸分析专用柱,并优化HPLC检测色谱条件。结果表明:梯度洗脱程序、流动相pH值、色谱柱温对分析时间、色谱峰分离及峰型具有重要影响。当最优色谱条件为:流动相A为0.1 mol/L无水乙酸钠缓冲溶液(pH6.4±0.1)-乙腈(66∶5),流动相B为乙腈-水(4∶1),流速1.0 mL/min,检测波长254 nm,色谱柱温40℃,梯度程序洗脱,35 min内可完全分离16种氨基酸,且各氨基酸在一定浓度范围内线性关系良好(R2均大于0.9986),加标回收率在83.84%-108.02%之间,RSD值均小于2.77%。该方法耗时短、操作简便、准确可靠,具有良好的精密度和稳定性。通过此方法研究分析伊枯草菌素A发酵过程中各游离氨基酸含量变化规律,发现其氨基酸浓度变化规律大致分为三类。     

高效液相色谱法测定大鼠血浆中来那度胺的浓度及其药动学(英文)

目的:建立高效液相色谱法测定大鼠血浆中来那度胺的浓度。方法:色谱柱采用VenusilASBC18column(4.6 mm×250mm,5μm)购自于博纳艾杰尔科技有限公司。样品采用梯度洗脱,流动相为乙腈和0.05%甲酸溶液,流速为1.0 mL/min,检测波长为254 nm,以沙利度胺为内标。结果:来那度胺血药浓度的线性范围为0.1-5μg/mL,最低检测限为0.1μg/mL,三个浓度的QC样品(0.2,1 and 5μg/mL)的提取回收率分别为78.8±3.8,80.1±3.2 and 79.1±7.6%。结论:此方法准确、简便、灵敏度高,对来那度胺的血药浓度测定和药物代谢动力学研究极具价值。     

用高效液相色谱—电化学检测法快速、灵敏分析生物样本中的单胺类递质及其代谢产物

本实验用反相离子对色谱-电化学检测分析法,同时分离并测定生物样本中结构极为相似的单胺类递质及其代谢产物。实验采用等比洗脱,在30min内至少可测定九个这类化合物。生物样品的预处理简单,因而平均回收率能达到90％以上。十个化合物(包括3,4-二羟基苄胺)保留时间变异系数为0.73±0.18％(均值±标准差,下同);峰面积变异系数为1.11±0.45％;在50—100pg至40ng范围内,相夫系数为0.996±0.006。本文对我们所用的色谱分析条件进行了讨论。     

DNFB柱前衍生化RP-HPLC测定大黄种子氨基酸的含量

采用柱前衍生RP-HPLC法测定大黄种子中氨基酸的含量。6 mol/L盐酸水解得到氨基酸,以2,4-二硝基氟苯(DNFB)为柱前衍生化试剂,梯度洗脱。色谱柱为Gemimi-NX C18(4.6 mm×250 mm,5μm);流动相A相为0.1 M乙酸钠水溶液,B相为乙腈-水(1∶1),柱温37℃,检测波长360 nm。结果表明,三种正品大黄种子中均含有17种氨基酸,总量在11.30%~19.26%。该方法灵敏、准确,有良好的重复性和稳定性。     

10CM短柱快速分离3-MH的实验研究

本研究在改进后短程序基础上,对氨基酸分离柱进行了改进。改进后的分离柱长为10cm。比原来20cm长柱分离3—MH的时间缩短了近1/2。实验所得的(回收率为97.59%,分离度0.89±0.02。变异系数1.17)这些指标较国外用其它方法所得的结果有良好的相关性。多次测定结果说明长柱与短柱比较无明显差异。证明了短柱对3—MH含量无影响。这一改进所建立的方法大大地缩短了样品的分析时间,节约了大量进口试剂,开展这方面的工作将有利益提高严重烧伤、创伤后蛋白质代谢和营养学等方面的研究水平。     

两种柱前衍生反相高效液相色谱法测定血液和尿液中游离氨基酸

建立以PITC法和AQC法为柱前衍生试剂测定血液和尿液中游离氨基酸含量的测定方法。采用Waters-e2695操作系统,色谱柱为Shim-vp,ODS(250mm×4.6mm,5μm)(日本,岛津公司),以甲醇/乙腈/水和醋酸钠溶液(pH 6.5)为流动相,梯度洗脱。分别采用紫外和荧光检测器对血液和尿液中游离氨基酸进行含量测定。结果显示,两种衍生化方法灵敏度好、分离度高,具有良好的线性范围(r>0.990 0),准确度高(平均回收率为75.1%～127.0%),进样精密度好(RSD为0.12%～3.42%)。PITC法在尿液中游离氨基酸含量测定中显示了良好的测试准确性;而AQC法测定尿液中组氨酸、苏氨酸、脯氨酸超出线性范围,需要对尿样的前处理进行深入研究。     

柱前衍生反相高效液相色谱法测定绞股蓝茶叶中17种游离氨基酸含量

建立2,4-二硝基氟苯柱前衍生化-反相高效液相色谱法测定绞股蓝茶叶中17种游离氨基酸的含量。以Phenomenex Gemini NX C18(4.6mm×250mm,5μm)为分析柱,采用梯度洗脱,流动相A为0.05mol·L-1乙酸钠(pH=6.4,含0.1%N,N-二甲基甲酰胺),流动相B为乙腈-水(1∶1,v/v),检测波长为360nm,柱温35℃;经方法学考察,该方法具有良好的稳定性和重现性。测定结果表明,绞股蓝茶叶中17种游离氨基酸总量为39.79mg·g-1,其中人体必需氨基酸占游离氨基酸总量的36.57%。从氨基酸含量考虑,绞股蓝茶叶具备一定的开发利用价值。     

Measurement of branched chain amino acids in blood plasma by high performance liquid chromatography

A simple and rapid high performance liquid chromatographic technique is described for the separation and quantitation of plasma branched chain amino acids. After addition of a norleucine internal standard, plasma samples are acidified with acetic acid, and amino acids are separated from proteins and other plasma components by passage of the acidified plasma through an ion exchange resin. The ammonium hydroxide eluate from the resin is dried, phenylisothiocyanate derivatives are prepared, and the amino acids are separated on a Waters reverse-phase "Pico-Tag" column with an ultraviolet detector set at 254 nm. In addition to the branched chain amino acids (leucine, valine, and isoleucine), aspartate, glutamate, serine, threonine, alanine, and methionine are quantitated with high precision and accuracy, as verified by quantitative recovery and comparison with an automatic amino acid analyzer. The advantages of the method are its simplicity, speed, stability of derivatives, high reproducibility, low per-sample cost, and the use of a simple fixed-wavelength ultraviolet detector.     

Xterra RP18柱高效液相色谱法快速分离测定氨基酸

建立了一种用XterraRP1 8色谱柱快速分离测定水解氨基酸的方法。所采用的色谱条件是 :WatersAlliance系统 ,柱温 5 6℃ ,流速 1 .8ml/min ,检测波长 2 4 8nm ,梯度分离 ,运行周期 2 5min,柱反压低于 2 0 0 0Psi。在 1 7.5min内分离了包括AMQ、NH3 和牛磺酸在内的 2 1种氨基化合物 ,适应于复合氨基酸注射液、含牛磺酸的氨基酸口服液及水解氨基酸样品的分析测定     

Amino acid analysis using 1-naphthylisocyanate as a precolumn high performance liquid chromatography derivatization reagent

A method which uses 1-naphthylisocyanate as an HPLC precolumn derivatization reagent for amino acid analysis is described. Derivatization is carried out by adding the isocyanate dissolved in dry acetone to a buffered amino acid solution followed by extraction of the excess reagent with cyclohexane. The resulting naphthylcarbamoyl amino acids are stable and highly fluorescent, with excitation maxima at 238 and 305 nm and an emission maximum at 385 nm, for most amino acids. Ultraviolet detection near 222 nm, the absorption maximum, can also be employed. HPLC procedures permitting the analysis of protein hydrolysates, brain extract, cerebrospinal fluid, and blood plasma are presented. The method is particularly suitable for auto-sampler procedures since samples can be derivatized and diluted in advance and stored at room temperature in the sampler while awaiting injection. Other advantages include high sensitivity, the possibility of recovering the derivatives from the column effluent, and the absence of a reagent peak in the chromatograms.     

Rapid determination of amino acids in biological samples using a monolithic silica column

A high-performance liquid chromatography method in which fluorescence detection is used for the simultaneous determination of 21 amino acids is proposed. Amino acids were derivatized with 4-fluoro-7-nitro-2,1,3-benzoxadiazole (NBD-F) and then separated on a monolithic silica column (MonoClad C18-HS, 150 mm × 3 mm i.d.). A mixture of 25 mM citrate buffer containing 25 mM sodium perchlorate (pH 5.5) and acetonitrile was used as the mobile phase. We found that the most significant factor in the separation was temperature, and a linear temperature gradient from 30 to 49°C was used to control the column temperature. The limits of detection and quantification for all amino acids ranged from 3.2 to 57.2 fmol and 10.8 to 191 fmol, respectively. The calibration curves for the NBD-amino acid had good linearity within the range of 40 fmol to 40 pmol when 6-aminocaproic acid was used as an internal standard. Using only conventional instruments, the 21 amino acids could be analyzed within 10 min. This method was found to be suitable for the quantification of the contents of amino acids in mouse plasma and adrenal gland samples.     

Validation of the determination of amino acids in plasma by high-performance liquid chromatography using automated pre-column derivatization with o-phthaldialdehyde

A sensitive and reproducible fully automated method for the determination of amino acids in plasma based on reversed-phase high-performance liquid chromatography and o-phthaldialdehyde pre-column derivatization is described. A 5-μm Spherisorb ODS 2 column (125 × 3 mm I.D.) was selected for routine determination. Over 40 physiological amino acids could be determined within 49 min (injection to injection) and 48 samples could be processed unattended. The coefficients of variation for most amino acids in plasma were below 4%. We were also able to measure trace amounts of amino acids in plasma normally not detected in a routine analysis. The results obtained with the method described compared favourably with those of conventional amino acid analysis (r = 0.997) and were in excellent agreement with those of other laboratories (r = 0.999).     

Application of amino acid analysis by high-performance liquid chromatography with phenyl isothiocyanate derivatization to the rapid determination of free amino acids in biological samples

An amino acid analysis by reversed-phase high-performance liquid chromatography after precolumn derivatization with phenyl isothiocyanate was adapted to the determination of free amino acids in plasma or other biological fluids and in tissue homogenates. Preparation of samples included deproteinization by 3% sulphosalicylic acid, and careful removal under high vacuum of residual phenyl isothiocyanate after derivatization. A Waters Pico-Tag column (15 cm long) was used, immersed in a water-bath at 38°C. In rat or human plasma, separation of 23 individual amino acids, plus the unresolved pair tryptophan and ornithine, was obtained within 13 min. Including the time for column washing and re-equilibration, samples could be chromatographed at 23-min intervals. Variability was tested for each amino acid by calculating the coefficients of variation of retention times (less than 1% in the average) and peak areas (less than 4% for both intra-day and inter-day determinations). The linearity for each standard amino acid was remarkable over the concentration range 3–50 nmol/ml. The mean recovery of amino acid standards added to plasma prior to derivatization was 97 ± 0.8%, except for aspartate (82%) and glutamate (81%). This method is rapid (almost three samples per hour can be analysed, more than in any other reported technique), with satisfactory precision, sensitivity and reproducibility. Therefore, it is well suited for routine analysis of free amino acids in both clinical and research work.     

Simple and rapid quantitative high-performance liquid chromatographic analysis of plasma amino acids

A simple and rapid high performance liquid chromatographic method for the determination of plasma amino acids was developed. The method uses minimal sample volume and automated online precolumn derivitization of amino acids with o-phthalaldehyde and fluorescent detection. Amino acids are separated by a simplified gradient without column heating. The assay is linear from 5 to 1000 micromol/L for all amino acids. Recovery of amino acids was between 91 and 108%, intra-assay coefficient of variation (CV) was 1-7%, and inter-assay CV was 2-12%. The simple sample preparation and minimal sample volume make the method useful for the quantitation of amino acids in both patient and experimental animal samples.     

Preparation of Peptides Containing Any Desired Amino Acid: Methionyl Peptides of Bovine Rhodopsin

A general method is described which allows the identification and preparation of peptides containing any amino acid of interest. The method has been applied to isolation of the methionyl peptides from a peptic digest of oxidized bovine rhodopsin. The peptide digestion mixture is first partially separated by ion exchange column chromatography. Location of peptides containing the desired amino acid is performed by amino acid analysis of acid hydrolyzed column fractions by high voltage paper electrophoresis. Peptides are further purified and prepared by peptide mapping, elution, and amino acid analysis using inexpensive high capacity techniques. Peptide sequencing is performed by a manual dansyl-Edman method well adapted for rapidly processing large numbers of samples. The methods are particularly well suited for detection and preparation of peptides containing amino acids for which there is no specific detection method.     

Reversed-phase high-performance liquid chromatography separation of dimethylaminoazobenzene sulfonyl- and dimethylaminoazobenzene thiohydantoin-amino acid derivatives for amino acid analysis and microsequencing studies at the picomole level

A simple and fast reversed-phase high-performance liquid chromatographic method has been developed for the complete separation of 35 dimethylaminoazobenzene sulfonyl (DABS)-amino acids and by-products. This method allows simultaneous determination of primary and secondary amino acids which can be present in protein and peptide hydrolysates and also detects the presence of cysteic acid, S-sulfocysteine, hydroxyproline, taurine, norleucine, cystine, and delta-hydroxylysine. The precolumn derivatization of amino acids with dimethylaminoazobenzene sulfonyl chloride (DABS-Cl) is simple and quick (10 min at 70 degrees C) and allows the complete reaction of primary and secondary amino acids. The separation of the compounds under investigation is achieved in 25 min using a reversed-phase 3-microns Supelcosil LC-18 column at room temperature. The versatility of the proposed method is documented by amino acid determination on protein samples obtained using different hydrolysis techniques (HCl, methane-sulfonic acid, and NaOH), with attention given to the detection of tryptophan in protein samples with high sugar concentration. Furthermore, we have reported the experimental conditions necessary to apply this method to the amino acid analysis of very low amount of proteins (1 to 5 micrograms) electroeluted from a stained band after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The stability of DABS-derivatives, the short time of analysis, the high reproducibility and sensitivity of the system, and the complete resolution of all compounds of interest make this method suitable for routine analysis. Furthermore, we have also developed a fast reversed-phase high-performance liquid chromatographic method for the complete separation of dimethylaminoazobenzene thiohydantoin (DABTH)-amino acids. The separation of the compounds under investigation is obtained, at room temperature, in less than 18 min using a reversed-phase Supelcosil LC-18 DB column, 3-micron particles, and also allows the complete separation of DABTH-Ile, DABTH-Leu, and DABTH-Norleu. The short time of analysis, together with the high reproducibility of the system and its sensitivity at picomole levels, make this method very suitable for the identification of DABTH-amino acids released during microsequencing studies of proteins and peptides with the dimethylaminoazobenzene isothiocyanate reagent. In addition, we have shown that it is possible to obtain complete separation of DABTH-amino acids also under isocratic conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Measurement of free amino acid levels in ultrafiltrates of blood plasma by high-performance liquid chromatography with automatic pre-column derivatization

Although there are many techniques available for the analysis of amino acids, deproteinization is still one of the major problems in the analysis of amino acids in physiological fluids. The method used to prepare the plasma and to remove the plasma protein has a marked effect on the final results. The most widely used method of deproteinization is precipitation with 5-sulphosalicylic acid followed by centrifugation to remove the precipitated protein. We have not had success in using this deproteinization agent for the analysis of plasma amino acids by a high-performance liquid chromatographic method with automatic pre-column o-phthaldialdehyde—3-mercaptopropionic acid and 9-fluorenylmethyl chloroformate derivatization because of the adverse effect of the sulphosalicyclic acid supernatant on the quantitation and separation. Ultrafiltration was used as an alternative method for the preparation of plasma samples in this experiment. The results were satisfactory for the analysis of plasma amino acids in 1500 samples during a period of four years. Some factors that might influence the results of the ultrafiltration were investigated.