基于固定化酶的流动荧光法测定血清中的葡萄糖

本文将固定化酶柱，光纤以及停流技术结合起来，研究了以廉价而易得的硫胺素为荧光底物的葡萄糖的荧光分析，提出了一种快速、简便、精确地测定葡萄糖的新方法。其线性范围为１．０￣６０．０ｍｇ／Ｌ，线性相关系数为０．９９９，检测限为０．１５ｍｇ／Ｌ。以５．０ｍｇ／Ｌ的葡萄糖作精度试验，ＲＳＤ％＝２．１％（ｎ＝１１）。该方法已成功地用于血清中葡萄糖的测定，结果与光度法相符。     

高效液相色谱-柱后固定化酶反应器-电化学检测法分析大鼠脑微透析液中的乙酰胆碱和胆碱

 建立了用高效液相色谱分离－柱后固定化酶反应器酶解－电化学检测器检测酶解最终产物Ｈ２Ｏ２的方法，分析了麻醉和自由活动大鼠脑微透析液中乙酰胆碱（ＡＣｈ）和胆碱（Ｃｈ）的含量。至少在０．２～１００μｍｏｌ／Ｌ范围内ＡＣｈ和Ｃｈ的浓度与其响应的线性关系良好，它们的检测极限都可达５０ｆｍｏｌ。对高效液相色谱结合固定化酶反应器的分析方法作了简要的讨论。     

高效液相色谱-柱后固定化酶反应器-电化学检测法分析大鼠脑微透析液中的乙酰胆碱和胆碱

建立了用高效液相色谱分离－柱后固定化酶反应器酶解－电化学检测器检测酶解最终产物Ｈ２Ｏ２的方法，分析了麻醉和自由活动大鼠脑微透析液中乙酰胆碱（ＡＣｈ）和胆碱（Ｃｈ）的含量。至少在０．２～１００μｍｏｌ／Ｌ范围内ＡＣｈ和Ｃｈ的浓度与其响应的线性关系良好，它们的检测极限都可达５０ｆｍｏｌ。对高效液相色谱结合固定化酶反应器的分析方法作了简要的讨论。     

开管柱固定化葡萄糖氧化酶反应器的制备及其在流动注射分析中的应用

本文将葡萄糖氧化酶化学键合到粗糙化的玻璃毛细管内壁上,用开管柱固定化酶反应器-安培检测器进行葡萄糖的流动注射分析。讨论了流速对流动注射分析体系峰电流和分散度的影响,提出了测量开管柱固定化酶表观活力的方法。     

整体固定化酶反应器的研制

制作了微型整体柱型的固定化酶反应器。在500μm内径毛细管内,以乙烯基三甲氧基硅烷处理形成端基烯键,采用原位合成法,以甲基丙烯酸2-羟乙酯为功能单体,以乙二醇二甲基丙烯酸酯为交联剂制备了整体柱。整体柱表面的羟基经NaIO4氧化形成醛基后与胰蛋白酶的氨基进一步反应,实现胰蛋白酶的固定。在24s内,该酶反应器实现了肌红蛋白和细胞色素c的酶解,经MALDI-TOF MS鉴定,序列覆盖率分别达到65%和79%。     

固定化酶法测定血清中葡萄糖和胆固醇

本文讨论了一种灵敏、高选择性的方法分别测定葡萄糖和胆固醇,并介绍了成二醛固定化酶(葡萄糖氧化酶或胆固醇氧化酶)后产生的过氧化氢借助于鲁米诺-铁氰化钾发光反应由流动注射法测定。对血清中样品的前处理和反应试剂浓度的影响也分别作了研究。本法有良好的线性工作范围,连续进样100次仍能保持工作的稳定性,相对标准误差为3.8～5.2%。     

固定化酶反应器在高效液相色谱分析中的应用

高效液相色谱法(HPLC)是分离含多组分的复杂体系的最有效手段之一,但检测体系的灵敏度总不能令人满意。折光率检测器通用,但灵敏度不高;紫外、荧光、电化学检测器要求化合物须有生色团、荧光团和电活性基团。近年来,柱前和柱后标记方法发展较快,扩大了这些检测器的应用范围。在标记方     

固定化多酶级联反应器

多酶级联反应在生命活动过程中发挥着重要作用。固定化多酶级联反应器是将不同功能的酶通过物理化学或生物手段固定于特定载体上,以之模拟生物体内多种酶协同作用方式促使底物发生降解和转化等反应的新型仿生催化技术。该技术具有固定化酶的稳定性、可重复利用以及酶级联的高效协同催化等优点,近年来在生物传感、模拟生物学以及生物转化等领域得到越来越多的关注。本文从多酶级联反应原理、反应器制备、级联反应的影响因素及应用等方面对近年来固定化多酶级联反应器的进展进行详细评述,并展望其发展前景。     

高效液相色谱中固定酶柱后反应器的应用

本文评述了固定酶柱后反应器在高效液相色谱中的应用。阐述了高效液相色谱与固定酶柱后反应器联用的原理,介绍了固定酶柱后反应器的主要类型。评述了固定酶柱后反应器在生化分析和临床分析中的应用。引文43篇。     

氨基化树枝状介孔二氧化硅固定葡萄糖氧化酶用于检测葡萄糖

以三乙胺为碱源合成了树枝状介孔二氧化硅纳米粒子(DMSNs),并用3-氨基丙基三乙氧基硅烷(APTES)进行氨基修饰合成了氨基化树枝状介孔二氧化硅纳米粒子(DMSNs-NH₂),将其用于葡萄糖氧化酶(GOD)的固定化研究.采用扫描电子显微镜、透射电子显微镜、红外光谱仪、X射线衍射仪、氮气吸附仪及热重分析仪对固定化GOD(DMSNs-NH₂-GOD)进行了表征,测定了其活性及蛋白载量.结果表明,固定化GOD的直径约为200 nm,形状均一,呈分散的球形微粒;在最佳固定条件下,蛋白载量达225 mg/g,酶活性达215 U/mg;固定化GOD检测葡萄糖的最低检测限为0.0014 mg/mL.利用固定化GOD检测了血清和饮料中的葡萄糖,重复使用36次以上其相对酶活性仍剩余80%.该方法操作方便、准确度高,提高了酶的pH稳定性、热稳定性及重复使用性,降低了检测成本.     

Detection of Hydrogen Peroxide and Glucose Based on Immobilized C60‐Catalase Enzyme

The interaction between fullerene C60 and catalase enzyme was studied with a fullerene C60‐coated piezoelectric (PZ) quartz crystal sensor. The partially irreversible response of the C60‐coated PZ crystal sensor for catalase was observed by the desorption study, which implied that C60 could chemically react with catalase. Thus, immobilized fullerene C60‐catalase enzyme was synthesized and applied in determining hydrogen peroxide in aqueous solutions. An oxygen electrode detector with the immobilized C60‐catalase was also employed to detect oxygen, a product of the hydrolysis of hydrogen peroxide which was catalyzed by the C60‐catalase. The oxygen electrode/C60‐catalase detection system exhibited linear responses to the concentration of hydrogen peroxide and amount of immobilized C60‐catalase enzyme that was used. The effects of pH and temperature on the activity of the immobilized C60‐catalase enzyme were also investigated. Optimum pH at 7.0 and optimum temperature at 25 °C for activity of the insoluble immobilized C60‐catalase enzyme were found. The immobilized C60‐catalase enzyme could be reused with good repeatability of the activity. The lifetime of the immobilized C60‐catalase enzyme was long enough with an activity of 93% after 95 days. The immobilized C60‐catalase enzyme was also applied in determining glucose which was oxidized with glucose oxidase resulting in producing hydrogen peroxide, followed by detecting hydrogen peroxide with the oxygen electrode/C60‐catalase detection system.     

Lab‐on‐a‐Chip Biosensor for Glucose Based on a Packed Immobilized Enzyme Reactor

In this work, the development of a packed immobilized enzyme reactor (IMER) and its integration to a capillary electrophoresis microchip is described. The present microchip design differs from others, in the fact that the same design could be used with or without the particles and, just by changing the material used to pack the IMER, different analytes can be detected. The applied procedure involves the separation of the target analyte by capillary electrophoresis (CE), which is then coupled to a post‐column IMER that produces H₂O₂. The H₂O₂ produced is finally detected downstream at the surface of a working electrode. Glucose was detected above 100 μM by packing particles modified with glucose oxidase at the end of the separation channel. The analytical performance of the microchip‐CE has been demonstrated by performing the separation and detection of glucose and noradrenaline. Additions of fructose showed no effect on either the peak position or the peak magnitude of glucose. The microchip‐CE‐IMER was also used to quantify glucose in carbonated beverages with good agreement with other reports.     

甲壳胺-羧甲基纤维素钠高分子复合物固定酶的研究

本文采用天然高分子甲壳胺与羟甲基纤维素钠的高分子复合物作哉体,固定葡萄糖氧化酶和纤维素酶。得到的固定化酶活性较高、热稳定性好。固定化后的葡萄糖氧化酶比固定化前的最适反应温度提高50℃,固定化后的纤维素酶最适反应温度提高20℃。固定酶的贮存稳定性明显提高,并可反复使用。     

Simultaneous Determination of Glucose and L‐Glutamate Using a Capillary Enzyme Reactor with Electrochemical Detection

An electrophoresis capillary that incorporates two enzymes for the simultaneous determination of glucose and L ‐glutamate is described. The enzymes deposited along the separation capillary walls react with their respective substrate as they are separated during the electrophoresis to produce hydrogen peroxide that is detected by amperometry as the hydrogen peroxide zone emerges from the end of the capillary. Even though both enzyme reactions produce a common product, hydrogen peroxide, the hydrogen peroxide produced by each enzyme reaction stays in narrow zones that migrate the length of the capillary at different rates. The rate of migration for the individual H₂O₂ zones is consistent with the expected mobility of neutral glucose and of anionic L ‐glutamate, respectively. This property allows each enzyme substrate to be characterized in a single experiment and in the presence of other electroactive substances.     

羧基化碳纳米管修饰的安培型葡萄糖传感器测定血液中葡萄糖

在临床医学、生物过程、食品工业中葡萄糖的分析测定一直都占有重要地位。葡萄糖的测定以分光光度法[1]和酶电极法[2]为主。光度法的灵敏度和准确度低,选择性差。第一代酶电极通常采用分子氧作为电子媒介体,但此法背景电流大,易受环境中分子氧浓度的影响。逐渐发展起来的第二代     

溶胶凝胶固定化酶流动注射化学发光法测定人体血清中的胆固醇

采用溶胶凝胶技术分别固定了胆固醇脂酶和胆固醇氧化酶,制成固定化酶柱;人体血清中胆固醇脂在胆固醇脂酶的催化作用下生成胆固醇,胆固醇在胆固醇氧化酶的催化作用下被氧化产生H2O2,将其与鲁米诺发生耦合的化学发光反应,在模拟酶血红蛋白的催化作用下产生较强的化学发光。结合流动注射技术,建立了溶胶凝胶固定化酶流动注射化学发光法测定胆固醇的新方法。实验发现,发光强度与胆固醇的浓度在一定范围内呈良好的线性关系,总胆固醇的线性范围为1.01×10-6～2.02×10-4mol/L(r=0.9975);检出限为7.5×10-7mol/L;游离胆固醇的线性范围为5.0×10-8～2.18×10-5mol/L(r=0.9991);检出限为5.0×10-9mol/L。用生化分析仪(东芝TBA-120FR)与本方法进行对照,两种方法无显著性差异。本方法已应用于临床血清样品中胆固醇的检测。