高效阴离子交换-脉冲安培检测同时分析单糖和糖醛酸

建立了高效阴离子交换-脉冲安培检测(HPAE-PAD)同时分离测定8种单糖和2种糖醛酸的分析方法。以CarboPacPA20阴离子交换柱为分离柱,以2mmol/LNaOH溶液将8种单糖从分离柱上洗脱,而后用NaAc(50~200mmol/L)梯度淋洗2种糖醛酸,淋洗液流速为0.5mL/min,总分析时间为30min。在优化的分离测定条件下,8种单糖和2种糖醛酸的检出限为2.5~14.4μg/L(进样体积25μL,峰面积定量)。5mg/L的10种化合物的混合标准溶液连续7次进样,峰面积的相对标准偏差为0.3%~1.5%。用所建立的方法测定了多糖水解液和木材半纤维素水解液中的单糖和糖醛酸含量。     

高效凝胶渗透色谱及高效液相色谱和电喷雾-离子阱质谱法联用测定构成芦荟多糖的单糖

利用高效凝胶渗透色谱(HPGPC)测定芦荟浓缩液和芦荟粉中多糖的纯度和相对分子质量,使用1-苯基-3-甲基-5-吡唑啉酮(PMP)作为柱前衍生试剂分别对样品和其水解产物进行衍生,结合高效液相色谱(HPLC)分离和电喷雾-离子阱质谱(ESI-MS)检测分析其单糖组成.结果表明:组成芦荟中多糖的单糖主要是甘露糖和葡萄糖.     

单糖的柱前衍生化高效液相色谱及胶束电动毛细管色谱分析的对比研究

 采用1-苯基-3-甲基-5-吡唑啉酮(PMP)衍生糖类物质,通过简化衍生方法,优化分析条件,采用胶束电动毛细管色谱(MEKC)和高效液相色谱(HPLC)两种方法对5种还原单糖的PMP衍生物实现了良好的分离。5种还原单糖衍生物的保留时间的重现性较好(MEKC法的相对标准偏差(RSD)小于5%(n=5),HPLC法的RSD为0.23%(n=5))。用所建立的两种方法对实际样品中的糖进行了分析,结果表明所建方法可作为实际样品中单糖分析的常规方法。     

PMP柱前衍生高效液相色谱法分析杜氏盐藻多糖的单糖组成

建立了柱前PMP衍生高效液相色谱法分离检测8种中性糖、2种糖醛酸及2种糖胺的方法。筛选出适合PMP衍生物分离的色谱柱为Ec lipse XDB-C18,以0.1 mol/L磷酸盐缓冲液-乙腈为流动相,考察了pH值和乙腈体积分数对各种糖的PMP衍生物的保留及分离的影响,确定最佳pH值为6.7,最佳乙腈体积分数为17%;比较了不同衍生反应时间和萃取除杂前不同量盐酸中和反应产物时醛糖-PMP衍生物的峰面积大小变化,从而得到较佳的样品衍生化条件。应用优化的色谱条件和样品制备方法,测定了由杜氏盐藻提取纯化的多糖级分PD4 a和PD4b的单糖组成,其测定结果与高效阴离子交换色谱法的结果基本一致。     

氨基苯甲酸衍生化高效液相色谱法 分析多糖中的单糖及糖醛酸组成

衍生反相离子对色谱法同时分离检测多糖中单糖及糖醛酸组成的方法,筛选出适合于p-AMBA糖衍生物分离的色谱柱,考察了流动相组成对9种单糖和两种糖醛酸的p-AMBA衍生化产物的保留值及分离的影响,优化了反应温度和反应时间等衍生化条件,并应用优化的分析方法测定了螺旋藻中的单糖和糖醛酸的组成。采用紫外检测时,方法的检出限为 (2.55～13.4)×107mol/L;采用荧光检测时,方法的检出限为(3.38～176)×108 mol/L。     

气相色谱-质谱联用同时分析新型细菌多糖中的单糖和糖醛酸

对纯化的新型细菌多糖进行酸水解,用乙硫醇-三氟乙酸和醋酐-吡啶体系先后对酸水解物进行衍生,与之前报道不同的是糖醛酸得到有效衍生化。以木糖为内标,采用气相色谱-质谱联用(GC-MS)定量分析该多糖酸水解物中单糖和糖醛酸衍生物发现,该多糖的糖链由岩藻糖、葡萄糖、葡萄糖醛酸和半乳糖组成,其相对物质的量比为1.50:1.0:0.79:2.06;中性糖比例与糖醇乙酸酯化分析岩藻糖、葡萄糖和半乳糖的相对物质的量比(1.76:1.0:1.98)接近;糖醛酸咔唑法与该方法分析葡萄糖醛酸的含量分别为16.19%和14.85%。以上结果表明所建立的衍生化方法及GC-MS同时定量分析多糖酸水解物中单糖和糖醛酸的方法可行。此外还对葡萄糖醛酸的质谱裂解机理进行了阐述。     

藏药蕨麻多糖水解单糖的毛细管区带电泳分离研究

以1-萘基-3-甲基-5-吡唑啉酮(NMP)为柱前衍生试剂,探讨了毛细管区带电泳模式下对藏药蕨麻多糖水解液中单糖的分离条件。实验采用58.5 cm×50μm i.d.毛细管(有效长度50 cm),55 mmol/L硼酸盐缓冲溶液(pH=9.46),柱温20℃,分离电压22 kV,进样10 s。该法不加任何添加剂,9种单糖可高效、快速基线分离,实现了对藏药蕨麻多糖水解液中单糖的分离和定量分析,结果令人满意。     

柱前衍生化HPLC法测定酵母细胞壁中的甘露聚糖与β-葡聚糖

采用1-苯基-3-甲基-5-吡唑啉酮(PMP)为柱前衍生化试剂,结合反相高效液相色谱法,建立了同时测定酵母细胞壁中甘露聚糖和β-葡聚糖的方法。样品中的多聚糖经盐酸高温水解得到甘露糖和葡萄糖,经PMP衍生后,以0.02 mol/L乙酸铵-乙腈(80.5∶19.5)为流动相等度洗脱,反相C18柱(4.6 mm×250 mm,5μm)分离,紫外检测器(波长250 nm)检测,所测2种单糖的含量通过换算后得到甘露聚糖和β-葡聚糖的含量。结果表明,甘露糖和葡萄糖在10.0~1 000 mg/L质量浓度范围内与对应峰面积呈良好的线性关系,相关系数(r2)大于0.999。样品在28.0~80.0 mg范围内加标水平的平均回收率为88.1%~91.0%,相对标准偏差(RSD)小于3%,甘露糖和葡萄糖的检出限(LOD)分别为0.10 mg/L和0.08 mg/L。该方法灵敏度高、准确性好、实用可靠,适用于酵母细胞壁样品中甘露聚糖和β-葡聚糖含量的分析测定。     

高效液相色谱法分析新型细菌多糖中单糖和糖醛酸组成

建立了柱前1-苯基-3-甲基-5-吡唑啉酮(PMP)衍生-高效液相色谱法,分离检测新型细菌多糖中5种单糖及糖醛酸组成的分析方法。新型细菌多糖中加入单糖内标木糖后,经3mol/L三氟乙酸水解,再用PMP进行衍生化,采用XBridgeTMC18柱(250×4.6mm,5μm),以50mmol/L KH2PO4溶液(pH=5.5)和乙腈为流动相,在245nm波长检测。定量分析结果表明,该多糖由甘露糖、葡萄糖醛酸、葡萄糖、半乳糖和岩藻糖组成,其质量比为1.77∶0.44∶8.52∶1.32∶1.67。该方法重现性良好,能够快速对多糖样品进行组成分析。     

1-(2-萘基)-3-甲基-5-吡唑啉酮衍生试剂的制备及其在高效液相色谱-质谱法测定糖类化合物中的应用

以1-(2-萘基)-3-甲基-5-吡唑啉酮(NMP)作为柱前衍生试剂,建立了简单、灵敏的糖类组分的反相高效液相色谱测定方法。NMP与糖在氨为催化剂的条件下,于70 ℃下反应可获得稳定的衍生产物。在Hypersil ODS 2反相色谱柱上,实现了8种单糖的基线分离。衍生物线性相关系数均大于0.9985,检出限为0.58～1.1 pmol。利用柱后在线串联质谱的电喷雾电离正离子模式监测,获得了各组分的质谱定性及裂解规律,特别是m/z 473的特征碎片离子可作为单糖NMP衍生物的判定依据。与1-苯基-3-甲基-5-吡唑啉酮(PMP)相比,NMP对糖的衍生化具有灵敏、简单、质谱裂解规律性强、重现性好等优点。该方法用于测定油菜花粉多糖中的单糖组成,结果令人满意。     

Analysis of Low Molecular Weight Carbohydrates in Food and Beverages: A Review

This review presents a study of new advances in chromatographic methods and capillary electrophoresis for the analysis and quantification of carbohydrates in food and drink that have been made in essentially the last seven years (1995–2002). All the main groups of sugars have been considered: monosaccharides, disaccharides, trisaccharides, oligosaccharides, related compounds such as alditols, alditol glycosides, polyols, amino sugars, deoxy sugars, uronic acids and aldonic acids. The chromatographic methods referred to are High Performance Liquid Chromatography (HPLC), Gas Chromatography (GC) and related techniques (AMD-HPTLC: High Performance Thin-Layer Chromatography with Automated Multiple Development). Capillary Electrophoresis (CE) was also discussed.     

Analysis of microbial extracellular polysaccharides in biofilms by HPLC. Part I: development of the analytical method using two complementary stationary phases

The investigation of microbial extracellular polymeric substances (EPS) is helpful for the implementation of analytical methods which are suitable for biofilm analysis in order to understand the architecture and function of biofilms. A procedure for the qualitative and quantitative determination of various monosaccharides, oligosaccharides and uronic acids as important components of the carbohydrate fraction of microbial EPS by high-performance liquid chromatography (HPLC) and refractive index (RI)/UV detection is presented. Porous graphitic carbon and lead-form cation-exchanger have been examined as stationary phases. Therefore, two complementary HPLC methods are presented. To simulate the conditions of hydrolysis, the influences of various salts, acids and alkalis as matrix components have been investigated. Furthermore, the dependencies on the pH value and temperature of the mobile phase have been thoroughly studied. The results showed that the lead-form cation-exchanger is suitable for the separation of the neutral monosaccharides. However, for direct analysis after acidic hydrolysis with H₂SO₄, HCl or trifluoroacetic acid, an additional purification step, e.g., precipitation or lyophilization, is necessary when the cation-exchanger is used. With the exception of hydrolysis with HCl, the porous graphitic carbon stationary phase can be used without any further purification step and is appropriate for the separation of uronic acids and their γ-lactones. Additionally, the separation of a single monosaccharide and its derivatives is possible. Analytical parameters including the sensitivities, repeatabilities, limits of detection and limits of quantification of both HPLC methods using the RI detector are presented. The optimized method has been applied for the characterization of alginates and is also suitable for other extracellular polysaccharides in biofilms. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorised users.     

Thin-layer electrophoretic separation of monosaccharides, oligosaccharides and related compounds on reverse phase silica gel

The electrophoretic mobilities of monosaccharides, oligosaccharides, sugar alcohols and sugar acids were determined in 0.3 M borate buffer, pH 10, using thin-layer electrophoresis on silanized silica gel, pretreated with octanol-1. A rapid separation of a number of sugars, occurring in foods, could be achieved. Using a 0.05-0.1 M neutral solution of barium acetate as electrolyte, thin-layer electrophoresis allowed excellent and rapid separation as well as identification of all common uronic acids which are constituents of many acidic polysaccharides.     

高效液相色谱法分析生漆多糖中的单糖组成

采用μ－ＢｏｎｄａｐａｋＮＨ２ＴＭ色谱柱,以乙腈∶水∶甲醇（７０∶２５∶５,Ｖ／Ｖ）为流动相,利用示差折光检测器的高效液相色谱法对湖北毛坝大木、毛坝小木和建始３种生漆中漆多糖的单糖组成成分进行了直接分离分析,方法简便、快速、重现性好,回收率在９８．８％～１０３．６％之间,相对标准偏差在５％以下。     

HPLC Determination of Amino And Carbonyl Compounds with Dabsyl Chloride and Dabsyl Hydrazine

The new chromophoric reagent, 4-dimethylaminoazobenzene-4′-sulfonyl chloride (dabsyl chloride) was synthesized by reaction of sodium 4-dimethylaminoazobenzene 4′-sulfonate with phosphorus pentachloride. Dabsyl chloride reacted rapidly with all amino acids, aliphatic amines, and polyamines to form the corresponding dabsyl derivatives. The dabsyl amino acids (10^?11 mol) were visualized on thin layer plates and found to be photo-stable. During the last 12 years, in combination with HPLC, this newly developed labeling reagent has been shown to be very promising for microdetermination of amino acids, aliphatic amines and polyamines. Recently, another new chromophoric reagent, dabsylhydrazine, was synthesized from the reaction of dabsyl chloride with hydrazine. This reagent reacted readily with monosaccharides and carbonyl compounds to form the corresponding chromophoric dabsylhydrazones with strong absorbance at 425 nm. The application of this new reagent in HPLC analysis of monosaccharides was discribed. By use of Nova-PAK C₁₈ reverse-phase column and a concave gradient system of water and acetonitrile as eluent, the detection limits of monosaccharides in the range of 10 pmol have been reached.     

Uronic acid determination by high performance liquid chromatography with postcolumn fluorescence derivatization

To develop a fluorimetric high performance liquid chromatography (HPLC) technique for uronic acid microanalysis, a saline mobile phase and the postcolumn fluorimetric determination were combined. The detection limits of D-glucuronic, D-galacturonic and D-mannuronic acids were 7.19, 23.88 and 7.08 pmol, respectively. The proposed method was successfully applied to uronic acid microanalysis in a polysaccharide hydrolysate and a drink.     

A study of the polysaccharides from the stems ofAlcea hyrcana

Conclusions 1. Water-soluble polysaccharides have been isolated from the bark and stems ofAlcea hyrcana Grossh. with yields of 2.2% and 1.6%, respectively; they contain uronic acids, glucose, arabinose, and xylose.2.The quantitative amounts of these monosaccharides in samples of the isolated polysaccharides have been determined.Khimiya Prirodnykh Soedinenii, Vol. 6, No. 4, pp. 397–400, 1970     

High performance liquid chromatographic strategy for the analysis of exopolysaccharides extracted from pathogenic bacteria.

A high performance liquid chromatographic (HPLC) method has been developed to permit the rapid comparison of acidic polysaccharides of diverse compositions and the sensitive determination of their constituents. It is based on two combined analyses of the polysaccharide hydrolysates--a separation of the released compounds by ion-moderated partition chromatography with UV detection at two wavelengths and a separation of the sugar dansylhydrazine derivatives by reversed phase chromatography. The former permits identification and quantitation of uronic and carboxylic acids, the latter permits more sensitive and specific determination of the neutral aldoses. Some bacterial exopolysaccharides have been used to demonstrate the validity of this HPLC procedure for the chemical characterization of uronic acid-containing polysaccharides. This method appears to be useful for studying capsular polysaccharides, which are involved in the evasion of phagocytosis by pathogenic bacteria.