基于血红蛋白/纳米金修饰离子液体电极的电化学生物传感器

氧化还原蛋白质在工作电极上的直接电化学对于研究生命体系的电子转移机理,了解生命过程中的氧化还原机理,开发新型电化学生物传感器有着重要的意义~([1]).目前较多的工作是利用各种媒介体、促进剂和纳米材料修饰电极来实现蛋白质的直接电子转移.离子液体修饰电极(CILE)是以离子液体为修饰剂和粘合剂的一种新型化学修饰电极,在生物电分析化学已经应用.本文在CILE表面修饰纳米金用于血红蛋白的固定及其直接电化学行为的研究,取得了较好的结果.     

亚甲蓝修饰电极推动的血红素蛋白质直接电子转移反应

本文研究了几种血红素蛋白质包括牛血红蛋白, 人肌红蛋白和马心细胞色素C在亚甲蓝修饰电极上的非均相电子转移反应, 采用光透薄层光谱电化学法监测了血红素蛋白的直接电化学反应过程, 并进行了动力学研究。     

血红蛋白/纤维素季铵盐层层组装膜直接电化学及其生物传感研究

蛋白质与电极间的直接电子交换可以为生物活体内蛋白质的电子转移机制提供模型,同时也为构筑新型的生物传感器奠定基础~([1]).层层组装技术是近年来兴起的构建蛋白质多层薄膜的方法,此技术构建生物电化学传感器主要依靠聚阳离子与生物阴离子的静电引力在电极表面形成有序的多层薄膜~([2]).周金平等将纤维素与3-氯-2-羟丙基三甲基进行反应合成了一种新型的纤维素季铵盐~([3]),它是一种聚阳离子电解质.而通过pH的调节可使血红蛋白带上不同的电核~([4]).基于血红蛋白和纤维素季铵盐之间的静电引力,通过层层组装技术将血红蛋白和纤维素季铵盐逐层固定在玻碳电极表面,形成了有序排列的多层薄膜并实现了血红蛋白的直接电化学,在此基础上制备了H_2O_2无中继体电化学传感器.     

血红蛋白在纳米金修饰电极上的电化学研究

氧化还原蛋白在电极上的直接电化学研究不但能获得有关蛋白质和酶的热力学和动力学性质等重要信息,为开发新型生物传感器和生物反应器提供理论指导,而且对了解它们在生命体内的电子转移机理和生理作用机制具有重要意义。血红蛋白(Hb)是以血红素为辅基的蛋白质,在生物体中的主要     

不同乙氧基链段的非离子型表面活性剂在电极表面的电化学行为

蛋白质是生命的基础,研究氧化还原蛋白质的直接电化学不仅对模拟生物体系电子传递机理具有重要意义,而且为传感器的构筑提供了理论基础。遗憾的是,蛋白的直接电化学在裸电极上很难实现,许多研究者通过在电极上引入表面活性剂来克服该缺点.值得思考的是为什么在表面活性剂存在下,蛋白与电极之间才能实现直接电化学?甚至促进蛋白与电极之间的电子转移速率?因此研究表面活性剂在电极表面上的形态非常必要.我们主要讨论不同乙氧基单元的表面活性剂与蛋白之间在玻碳电极上的电子转移过程.结果表明不同表面活性剂提供给蛋白不同的微环境.当表面活性剂的乙氧基链长达到最佳值时,该修饰电极能固载更多的蛋白.我们利用紫外光谱法检测蛋白在固载过程中是否变性,同时也对所构筑的修饰电极的电催化性能进行表征.     

血红蛋白在纳米孔径氧化铝膜修饰电极上的直接电化学

运用电化学包埋法成功将血红蛋白(Hb)固定于纳米孔阳极氧化铝膜(AAO)修饰的玻碳电极(GC)表面, 制得Hb/PPy/AAO/GC修饰电极, 并对Hb/PPy/AAO/GC修饰电极的制备条件进行了优化. 研究了Hb/PPy/AAO/GC修饰电极在磷酸缓冲液(pH＝6.8)中的电化学行为, 探讨了血红蛋白在AAO修饰电极表面的直接电子转移机理. 结果表明阳极氧化铝膜不仅保持了血红蛋白的生物活性, 而且通过它的纳米尺寸效应, 实现了Hb与电极之间的直接电子转移. 其研究内容对生命科学和临床医学有着重要意义.     

血红蛋白在溶胶-凝胶纳米银修饰电极上的直接电化学

运用溶胶-凝胶技术将血红蛋白(Hb)固定于纳米银(AgNPs)修饰的玻碳电极(GCE)表面,制得溶胶-凝胶血红蛋白纳米银修饰电极(Sol-Gel/Hb/AgNPs/GCE)。优化了修饰电极的制备条件,研究了该修饰电极在B-R缓冲溶液(pH=4.10)中的电化学行为,探讨了Hb在AgNPs修饰电极表面的直接电子转移机理。结果表明:AgNPs不仅保持了Hb的生物活性,而且通过它的催化效应,实现了Hb与电极之间的直接电子转移。进一步的实验结果显示,固定在纳米银修饰电极表面的Hb能保持其对H2O2的生物电催化活性。     

血红蛋白在碳纳米管修饰碳糊电极上的直接电化学行为

利用吸附法将血红蛋白(Hb)固定在碳纳米管修饰碳糊电极表面,制成稳定的固载Hb碳纳米管修饰电极,研究了Hb在碳纳米管修饰电极上的直接电化学行为.固载Hb的碳纳米管修饰电极在pH=7.0的PBS（磷酸盐缓冲溶液）中有一对相当可逆的循环伏安氧化还原峰,为Hb血红素辅基Fe(Ⅲ)/Fe(Ⅱ)电对的特征峰.式电位为－0.160 V(vs SCE),随扫描速度变化很小.电子转移数为1.021,近似为一个辅基发生电子转移.Hb在碳纳米管修饰电极表面的电子转移常数为0.0816 s－1,远大于亚甲蓝作媒介体时Hb的电子转移反应速率常数.应用于过氧化氢、三氯乙酸和硝基苯等的电催化还原,固定在碳纳米管修饰碳糊电极的血红蛋白表现出稳定且较高的催化活性.     

血红蛋白和SiO2凝胶层层组装膜在碳纳米管/金纳米粒子修饰电极界面上的直接电化学及电催化研究

以SiO2凝胶膜和蛋白质交互组装法固定血红蛋白(Hb), 对其进行了电化学和电催化研究. 首先制备碳纳米管/金纳米粒子复合材料修饰的MWNTs-Au/GC电极, 为防止蛋白质在电极表面流失, 将Hb和自制的SiO2凝胶膜交替滴涂到电极表面, 得到SiO2/Hb层层组装膜修饰电极, 即{SiO2/Hb}n/MWNTs-Au/GC电极, n=2为优化层数. Hb在{SiO2/Hb}2/MWNTs-Au/GC电极上仍能保持其特有的生物活性, 并能与电极进行稳定快速的电子直接转移, 同时表现出过氧化物酶特性, 对H2O2具有良好的生物电催化还原能力.     

血红蛋白在二维纳米金Langmuir—Blodgett单层膜修饰电极上的直接电化学

利用Langmuir-Blodgett(LB)技术在氧化铟锡(ITO)电极上制备了分散均匀的二维纳米金单层膜,并将血红蛋白(Hb)直接固定于该修饰电极表面,研究了Hb在电极上的直接电化学行为.实验结果表明:纳米金可以改善Hb和电极间的直接电子传递,提高电子传递效率.Hb/Nano-Au修饰电极在pH 5.0～9.0范围内的式电位与溶液pH呈线性关系,斜率为-57 mV/pH,说明Hb的电子传递过程伴随质子转移;该修饰电极对H2O2具有良好的催化作用,在0.1 mol/L pH 7.0 的磷酸盐缓冲溶液(PBS)中,H2O2在2.5×10-6～4.1×10-4 mol/L浓度范围内与响应电流呈良好的线性关系,检出限为6.2×10-7 mol/L;其异相电子转移速率常数为0.66 s-1,米氏常数为0.20 mmol/L.     

纳米碳管电极上氧的电催化还原

以聚四氟乙烯为粘结剂制成了多壁纳米碳管（MWNT）电极.采用恒电位阶跃法和循环伏安法研究了MWNT电极在碱性溶液中的电化学行为，并对碱性溶液中溶解氧在该电极上的电化学还原行为进行了研究.实验结果表明： MWNT电极具有比石墨电极更高的孔隙率和电化学表面积；MWNT电极上O2还原成的反应为准可逆过程；在5～50 mV•s－1的扫描速率范围内，阴极峰电流与扫描速度成线性关系，表明MWNT电极上O2还原成的反应受吸附控制；对碱性溶液中的氧还原反应， MWNT比石墨具有更高的催化活性.     

基于ITO电极的细胞色素c吸附层的直接电化学

采用未经修饰的铟锡氧化物(ITO)工作电极直接探测到了细胞色素c(Cytc)吸附层的氧化还原峰,并得出了Cytc的表面浓度,随着溶液浓度从2μmo·lL-1增大到10μmo·lL-1,Cytc的表面浓度相应地从0.35×10-12mo·lcm-2增大到1.53×10-12mo·lcm-2.实验获得的表面浓度倒数与溶液浓度倒数的准线性关系说明Cytc在ITO表面的吸附基本满足Langmuir等温吸附理论.对Cytc溶液的循环伏安测试结果表明参与电极反应的Cytc包括游离分子和吸附分子,前者的贡献大于后者,电极反应主要受扩散控制并呈准可逆过程.根据Nicholson方法估算得到反应物的标准异相速率常数的平均值为1.65×10-3cm·s-1.实验结果显示在室温下放置1h后Cytc吸附层电化学活性部分丧失,在80℃下放置1h后吸附层完全失活.失活的Cytc吸附层对铁氰化钾溶液在Au电极上的电极反应具有明显的阻碍作用.     

Direct electrochemistry and bioelectrocatalysis of hemoglobin immobilized on carbon black

It is reported for the first time that hemoglobin (Hb) was immobilized on the surface of carbon black powders modified at the surface of a glassy carbon electrode. The cyclic voltammetric results showed that the immobilized Hb could undergo a direct quasi-reversible electrochemical reaction. Its formal potential, E(0), is -0.330 V in phosphate buffer solution (pH 6.9) at a scan rate of 100 mV/s and is almost independent of the scan rate in the range of 40-200 mV/s. The dependence of E(0), on the pH of the buffer solution indicated that the conversion of Hb-Fe(III)/Hb-Fe(II) is a one-electron-transfer reaction process coupled with one-proton-transfer. The experimental results also demonstrated that the immobilized Hb retained its bioelectrocatalytic activity for the reduction of H(2)O(2). Furthermore, the immobilized Hb can be stored at 4 degrees C for several weeks without any loss of the enzyme activity. Thus, the immobilized Hb may be used as a biocathodic catalyst in biofuel cells.     

Electrochemical and electrocatalytic properties of myoglobin and hemoglobin incorporated in carboxymethyl cellulose films

Protein-CMC films were made by casting a solution of myoglobin (Mb) or hemoglobin (Hb) and carboxymethyl cellulose (CMC) on pyrolytic graphite electrodes. In pH 7.0 buffers, Mb and Hb incorporated in CMC films gave a pair of well-defined and quasi-reversible cyclic voltammetric peaks at about -0.34 V vs. SCE, respectively, characteristic of heme Fe(III)/Fe(II) redox couples of the proteins. The electrochemical parameters such as apparent standard heterogeneous electron transfer rate constants (k(s)) and formal potentials (E degrees ') were estimated by square wave voltammetry with nonlinear regression analysis. In aqueous solution, stable CMC films absorbed large amounts of water and formed hydrogel. Scanning electron microscopy of the films showed that interaction between Mb or Hb and CMC would make the morphology of dry protein-CMC films different from the CMC films alone. Positions of Soret absorbance band suggest that Mb and Hb in CMC films retain their secondary structure similar to the native states in the medium pH range. Trichloroacetic acid, nitrite, oxygen, and hydrogen peroxide were catalytically reduced at protein-CMC film electrodes.     

Electrochemical study of the thionine dye incorporated into ZSM-5 and HZSM-5 zeolites

The electrochemical properties of thionine dye adsorbed into ZSM-5 and HZSM-5 zeolites (TH/ZSM-5, TH/HZSM-5) are studied in 0.5 M KCl solution. The dye is strongly retained and not easily leached from the zeolites matrix. The samples are incorporated into the carbon paste electrode (TH/ZSM-5/P, TH/HZSM-5/P) for cyclic voltammetric measurements. The redox reactions of thionine incorporated into ZSM-5 zeolite contain a quasi-reversible, two-electron one proton in the pH range 1 to 10, but thionine-loaded HZSM-5 zeolite undergoes a quasi-reversible two-electron two-protons redox reaction under acidic conditions and a one proton two-electron redox reaction takes place under basic conditions. The separation of the anodic and cathodic potentials (E _p) is high in thionine-loaded zeolites (>100) with respect to the solution of thionine (E _p = 34 for ZSM-5/P and 36 mV for HZSM-5/P), indicating that there are strong interaction between thionine molecules and the zeolites. The midpoint potentials (E _m) for TH/ZSM-5/P and TH/HZSM-5/P are −0.203 and −0.381 V, respectively. However, the midpoint potentials for the solution of thionine for the electrode system of ZSM-5/P and HZSM-5/P are −0.335 and −0.407 V, respectively. Thus, thionine dye molecules incorporated into the zeolites can be reduced more easily with respect to solution of thionine. In various electrolyte solutions, the midpoint potentials remains constant, but the midpoint potential of the thionine-zeolite electrodes depends on the solution pH. Influence of the pH of the solution on the midpoint potential of an immobilized dye reveals that thionine molecules are accessible to protons. This property is ascribed to the formation of mesopores in the structure of our zeolites suffering from a calcination step. Published in Russian in Elektrokhimiya, 2007, Vol. 43, No. 7, pp. 794–800. The text was submitted by the authors in English     

Direct electron transfer and bioelectrocatalysis of hemoglobin on nano-structural attapulgite clay-modified glassy carbon electrode

Direct electrochemistry of hemoglobin (Hb) on natural nano-structural attapulgite clay film-modified glassy carbon (GC) electrode was investigated. The interaction between Hb and attapulgite was examined using UV-vis, FTIR spectroscopy, and electrochemical methods. The immobilized Hb displayed a couple of well-defined and quasi-reversible redox peaks with the formal potential (E(0')) of about -0.366 V (versus SCE) in 0.1 M phosphate buffer solution of pH 7.0. The current was linearly dependent on the scan rate, indicating that the direct electrochemistry of Hb in that case was a surface-controlled electrode process. The formal potential changed linearly from pH 5.0 to 9.0 with a slope value of -48.2 mV/pH, which suggested that a proton transfer was accompanied with each electron transfer in the electrochemical reaction. The immobilized Hb exhibited excellent electrocatalytic activity for the reduction of hydrogen peroxide without the aid of an electron mediator. The electrocatalytic response showed a linear dependence on the H(2)O(2) concentration ranging from 5.4 x 10(-6) to 4.0 x 10(-4) M with the detection of 2.4 x 10(-6) M at a signal-to-noise ratio of 3. The apparent Michaelis-Menten constant K(M)(app) for the H(2)O(2) sensor was estimated to be 490 microM, showing a high affinity.     

纳米溶胶-凝胶膜修饰电极及电化学催化性能

报道了以纳米硅溶胶-凝胶（sol-gel）膜为载体的化学修饰电极。用sol-gel法在金电极上固定亚甲蓝及硫堇，发现固定于纳米硅溶胶-凝胶膜内的亚甲蓝和硫堇均有良好的电化学活性，并对同时固定于膜内的NADH、血红蛋白等生物分子产生显著的催化氧化还原作用。     

表面活性剂与血红蛋白的作用对转移电子数的影响

将不同浓度(0.15-10.0 mmol·L-1)的双十二烷基二甲基溴化铵(DDAB)和血红蛋白(Hb)依次修饰到热解石墨电极(PG)上, 制备了稳定的Hb-DDAB/PG电极. 利用循环伏安和紫外光谱研究了Hb-DDAB/PG电极的性质. 由Laviron模型得到的转移电子数表明该电化学反应由双电子过程逐步过渡到单电子过程, 进而证明DDAB膜厚的增加导致血红蛋白亚基间作用的减弱和亚铁血红素的释放.     

Direct electrochemistry and electrocatalysis of hemoglobin in gelatine film modified glassy carbon electrode

Direct electrochemical and electrocatalytic behavior of hemoglobin (Hb) immobilized on glass carbon electrode (GCE) containing gelatine (Gel) films was investigated. The characteristics of Hb/Gel film modified GC electrode were performed by using SEM microscopy, UV-vis spectroscopy and electrochemical methods. The immobilized Hb showed a couple of quasi-reversible redox peak with a formal potential of −0.38 V (versus SCE) in 0.1 M pH 7.0 PBS. The formal potential changed linearly from pH 4.03 to 8.41 with a slope value of −52.0 mV pH⁻¹, which suggested that a proton transfer was accompanied with each electron transfer (ET) in the electrochemical reaction. The Hb/gelatine/GCE displayed a rapid amperometric response to the reduction of H₂O₂ and nitrite.