碳纳米管电极上辣根过氧化物酶的直接电化学

制备了碳纳米管修饰玻碳电极(CNT/GC).将辣根过氧化物酶(HRP)固定在CNT/GC电极表面,形成HRP-CNT/GC电极.研究了HRP的直接电子转移.实验结果表明,HRP在CNT/GC电极表面能进行有效和稳定的直接电子转移反应,其循环伏安曲线上表现出一对良好的、几乎对称的氧化还原峰;式量电位E^0'几乎不随扫速(至少在20～100 mV/s的扫速范围内)而变化,其平均值为(-0.319±0.002) V (vs. SCE, pH 6.9); HRP在CNT/GC电极表面直接电子转移的速率常数为(2.07±0.56) s^-1;式量电位E^0'与溶液pH 的关系表明HRP的直接电化学是(1e+1H⁺)的电极过程.进一步的实验结果显示,固定在CNT/GC电极表面的HRP能保持其对H₂O₂还原的生物电催化活性,而且能快速地响应H₂O₂浓度的变化.本文制备碳纳米管修饰电极和固定酶的方法具有简单和易于操作等优点,可用于获得其它生物氧化还原蛋白质和酶的直接电子转移.     

碳纳米管修饰电极上葡萄糖氧化酶的直接电子转移

制备了碳纳米管修饰玻碳电极(CNT/GC), 利用吸附的方法将葡萄糖氧化酶(GOx)固定到CNT/GC电极表面, 形成GOx-CNT/GC电极．研究了GOx的直接电子转移, 实验结果表明, GOx在CNT/GC电极表面没有发生变性, 能进行有效和稳定的直接电子转移反应, 其循环伏安图上表现出一对很好的、几乎对称的氧化还原峰; 式量电位E^0’几乎不随扫速(至少在10~140 mV·s^−1的扫速范围内)而变化, 其平均值为−0.456±0.0008 V (vs. SCE); GOx在CNT/GC电极表面直接电子转移的速率常数为1.74±0.42 s^−1, 比文献中报道的值大了数十倍; 进一步的实验结果显示, 固定在CNT/GC电极表面的GOx能保持其对葡萄糖氧化的生物电催化活性, 而且电催化活性很稳定. 文中制备碳纳米管修饰电极和固定酶的方法具有简单和易于操作等优点, 可用于获得其他生物氧化还原蛋白质和酶的直接电子转移.     

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.     

纳米二氧化钛对辣根过氧化酶催化作用

将辣根过氧化物酶(HRP)固定在二氧化钛(TiO2)纳米颗粒或纳米管修饰玻碳电极(GC)上,形成纳米TiO2微粒/HRP修饰GC电极和TiO2纳米管/HRP修饰GC电极.比较了HRP在纳米TiO2微粒、TiO2纳米管电极上的直接电子转移反应.实验表明,HRP在TiO2纳米管电极表面更能有效地促进它的电活性中心发生电子交换反应.此外,还测定了HRP标记抗体的电化学性能,为抗原抗体免疫反应信号的选择提供了参考依据.     

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.     

磷脂修饰化的石墨烯纳米复合物的制备及其直接电化学研究

通过非共价键修饰方法制备了兼具良好生物相容性和导电性的磷脂1-棕榈酰-2-油酰甘油-3-磷酸钠-石墨烯(POPG-GP)纳米复合物,并利用TEM,FT-IR,UV-vis,zeta电位等对其形貌和结构进行了表征.由于POPG-GP纳米复合材料在水溶液中呈现出较为明显的负电性,因此,可通过静电自组装方法将辣根过氧化物酶(HRP)进一步组装到POPG-GP修饰的玻碳(POPG-GP/GC)电极上,构筑HRP/POPG-GP/GC修饰电极.电化学实验结果表明,POPG-GP纳米复合物能够有效实现HRP与修饰电极之间的直接电子转移.此外,固载在修饰电极表面的HRP对底物H2O2还表现出良好的电催化活性.HRP/POPG-GP/GC修饰电极对H2O2的检测线性范围为3.5~210μmol/L,最低检出限为1.17μmol/L(S/N=3),灵敏度为356.6 mA?cm-2?M-1,Km值为0.45 mmol/L.     

基于明胶-碳纳米管的辣根过氧化物酶修饰电极在离子液体中的直接电化学

制备了明胶(Gel)-多壁碳纳米管(MWCNTs)纳米复合物,将其修饰在玻碳电极表面,再吸附辣根过氧化物酶(HRP),制得明胶-多壁碳纳米管-辣根过氧化物酶修饰电极(Gel-MWCNTs-HRP/GCE).该修饰电极在PBS中的循环伏安图上出现了一对峰形良好、几乎对称的氧化还原峰,式量电位为-0.356 V(vs.SCE),表明包埋在Gel-MWCNTs中的HRP与电极之间发生了直接电子传递.当扫速在20 ～ 180 mV/s时,氧化峰电流(Ipa)与还原峰电流(Ipc)均与扫速成正比,表明电极过程是受电子传递速率控制的表面传质过程.运用循环伏安法研究了修饰电极的电化学特性,探讨了工作电位、pH值、干扰物质等对修饰电极的影响.实验结果表明,HRP在修饰电极表面能有效和稳定地进行直接电子转移,并保持了其对过氧化氢(H2O2)的生物催化活性.进一步研究发现,在含有亲水性离子液体1-丁基-3-甲基咪唑四氟硼酸([BMIM]BF4)的溶液中,修饰电极对H2O2显示出更灵敏的催化活性,其线性范围为2.0×10-7～0.13 mol/L,检出限(S/N =3)为2.3×10-8 mol/L.该电极具有灵敏度高、重现性及稳定性好、使用寿命较长等优点,同时还显示了较好的抗干扰能力.     

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。     

酶法合成的葡萄糖氧化酶-纳米金复合物的直接电化学与生物传感

将NaAuCl₄、葡萄糖氧化酶（GOx）和葡萄糖混合,借一步酶促反应制得吸附GOx的金纳米颗粒（AuNPs）,再通过滴干修饰法研制了Nafion/GOx-AuNPs修饰的玻碳（GC）电极,并考察了该酶电极上GOx的直接电化学和生物传感性能. 这种酶法合成的GOx-AuNPs复合物有良好的酶直接电化学活性,也保持了GOx的生物活性,似可归因于酶法合成的纳米金更接近酶氧化还原活性中心的缘故. 该酶电极在-0.4 V（vs. SCE）电位下,其稳态电流下降与葡萄糖浓度（0.5 4 mmol·L^-1）成正比,检测下限0.2 mol·L^-1.     

Direct electron transfer of glucose oxidase on the carbon nanotube electrode

The direct electrochemistry of redox enzymes (or proteins) has received more and more attention[1—9]. These studies developed an electrochemical basis for the investigation of enzyme structure, mechanisms of redox transformations of enzyme molecules and metabolic processes involving redox transformations. From these studies, one can also find potential appli-cations of enzymes in biotechnology. For example, if an enzyme immobilized on electrode surface is ca-pable of the direct electron tra…     

Glucose Oxidase/Cellulose–Carbon Nanotube Composite Paper as a Biocompatible Bioelectrode for Biofuel Cells

Biofuel cells are devices for generating electrical energy directly from chemical energy of renewable biomass using biocatalysts such as enzymes. Efficient electrical communication between redox enzymes and electrodes is essential for enzymatic biofuel cells. Carbon nanotubes (CNTs) have been recognized as ideal electrode materials because of their high electrical conductivity, large surface area, and inertness. Electrodes consisting entirely of CNTs, which are known as CNT paper, have high surface areas but are typically weak in mechanical strength. In this study, cellulose (CL)–CNT composite paper was fabricated as electrodes for enzymatic biofuel cells. This composite electrode was prepared by vacuum filtration of CNTs followed by reconstitution of cellulose dissolved in ionic liquid, 1-ethyl-3-methylimidazolium acetate. Glucose oxidase (GOx), which is a redox enzyme capable of oxidizing glucose as a renewable fuel using oxygen, was immobilized on the CL–CNT composite paper. Cyclic voltammograms revealed that the GOx/CL–CNT paper electrode showed a pair of well-defined peaks, which agreed well with that of FAD/FADH_2, the redox center of GOx. This result clearly shows that the direct electron transfer (DET) between the GOx and the composite electrode was achieved. However, this DET was dependent on the type of CNTs. It was also found that the GOx immobilized on the composite electrode retained catalytic activity for the oxidation of glucose.     

Direct electrochemistry of glucose oxidase immobilized on NdPO4 nanoparticles/chitosan composite film on glassy carbon electrodes and its biosensing application

The direct electrochemistry of glucose oxidase (GOx) immobilized on a composite matrix based on chitosan (CHIT) and NdPO(4) nanoparticles (NPs) underlying on glassy carbon electrode (GCE) was achieved. The cyclic voltammetry and electrochemical impedance spectroscopy were used to characterize the modified electrode. In deaerated buffer solutions, the cyclic voltammetry of the composite films of GOx/NdPO(4) NPs/CHIT showed a pair of well-behaved redox peaks that are assigned to the redox reaction of GOx, confirming the effective immobilization of GOx on the composite film. The electron transfer rate constant was estimated to be 5.0 s(-1). The linear dynamic range for the detection of glucose was 0.15-10 mM with a correlation coefficient of 0.999 and the detection limit was estimated at about 0.08 mM (S/N=3). The calculated apparent Michaelis-Menten constant was 2.5 mM, which suggested a high affinity of the enzyme-substrate. The immobilized GOx in the NdPO(4) NPs/CHIT composite film retained its bioactivity. Furthermore, the method presented here can be easily extended to immobilize and obtain the direct electrochemistry of other redox enzymes or proteins.     

肌红蛋白在碳纳米管修饰电极上的直接电化学和电催化性能

将肌红蛋白(Mb)通过吸附的方法固定在碳纳米管(CNT)表面, 用AFM、XPS、UV-Vis和FTIR对其进行了表征, 研究了CNT对Mb直接电子转移反应的促进作用. 循环伏安结果表明, Mb在CNT表面能进行有效和稳定的直接电子转移反应, 其循环伏安曲线上表现出一对良好的、几乎对称的氧化还原峰; 在20−160 mV•s−1的扫速范围内, 式量电位E0′几乎不随扫速而变化, 其平均值为(−0.343±0.001) V (vs SCE, pH 7.0); Mb在CNT表面直接电子转移的表观速率常数为(3.11±0.98) s−1; 式量电位E0′与溶液pH的关系表明, Mb的直接电化学过程是一个有H+参与的电极过程. 进一步的实验结果显示, 固定在CNT表面的Mb能保持其对H2O2和O2还原的生物电催化活性.     

HRP在大孔笼状介孔分子筛FDU-12上的固定及直接电化学

用吸附的方法将辣根过氧化物酶(HRP)固定到三维笼状介孔分子筛FDU-12中, 傅立叶变换红外光谱(FTIR)和电化学交流阻抗谱结果表明, 固定后的HRP没有变性, 并表现出良好的直接电化学性质, 其式量电位(E0')为-0.325 V, 在40-300 mV·s-1范围内, 它不随扫描速率变化而变化. 电化学反应速率常数(ks)为1.200 s-1. 固定后的HRP对H2O2有稳定的电催化活性, 该固定酶的方法具有简单、易操作和电极稳定性良好等优点, 可用于获得其他酶或氧化还原蛋白质的直接电子转移以及第三代生物传感器电极的制备.     

Direct Electrochemistry of Hemoglobin Immobilized in Sodium Alginate Film on the Ionic Liquid [BMIM]PF6 Modified Carbon Paste Electrode

In recent years the direct electron transfer of redox protein on electrode surface has attracted great attentions1. Different kind of modified electrode and various supporting films for immobilization of proteins had been proposed. But most of them are ba…     

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.     

固载于壳聚糖-纳米金复合膜修饰玻碳电极上的葡萄糖氧化酶的直接电化学研究及其生物传感应用

通过将葡萄糖氧化酶固载于壳聚糖-纳米金复合膜内所构置的传感器,实现了葡萄糖氧化酶的直接电化学,并采用循环伏安法与电化学阻抗法对修饰电极进行了表征。研究表明：在除氧缓冲溶液中,葡萄糖氧化酶-壳聚糖-纳米金复合膜修饰电极表现出一对良好的氧化还原峰,这对峰归因于葡萄糖氧化酶的氧化还原,证明葡萄糖氧化酶被成功固载于复合膜内。电子传递速率常数为15.6 s-1,说明葡萄糖氧化酶的电活性中心与电极之间的电子传递很快。将壳聚糖与纳米金相结合还提高了葡萄糖氧化酶在复合膜内的稳定性并保持其生物活性,并可以用于葡萄糖检测。计算得到其表观米氏常数为10.1 mmol·L-1。而且,该生物传感器可以用于血样中葡萄糖含量的测定。     

Direct electrochemistry and electrocatalysis of hemoglobin entrapped in semi-interpenetrating polymer network hydrogel based on polyacrylamide and chitosan

Semi-interpenetrating polymer network (semi-IPN) hydrogel based on polyacrylamide (PAM) and chitosan was prepared to immobilize redox protein hemoglobin (Hb). The Hb-PAM-chitosan hydrogel film obtained has been investigated by scanning electron microscopy (SEM) and UV-VIS spectroscopy. UV-VIS spectroscopy showed that Hb kept its secondary structure similar to its native state in the Hb-PAM-chitosan hydrogel film. Cyclic voltammogram of Hb-PAM-chitosan film-modified glass carbon (GC) electrode showed a pair of well-defined and quasi-reversible redox peaks for Hb Fe(III)/Fe(II), indicating that direct electron transfer between Hb and GC electrode occurred. The electron-transfer rate constant was about 5.51 s(-1) in pH 7.0 buffers, and the formal potential (E degrees ') was -0.324 V (vs. SCE). The dependence of E degrees ' on solution pH indicated that one-proton transfer was coupled to each electron transfer in the direct electron-transfer reaction. Additionally, Hb in the semi-IPN hydrogel film retained its bioactivity and showed excellent electrocatalytic activity toward H(2)O(2). The electrocatalytic current values were linear with increasing concentration of H(2)O(2) in a wide range of 5-420 microM. The unique semi-IPN hydrogel would have wide potential applications in direct electrochemistry, biosensors and biocatalysis.     

Electrocatalysis of Hemoglobin in ZnO Nanoparticle/Ionic Liquid Composite Film Modified Glassy Carbon Electrode

A nanobiocompatible composite containing hemoglobin (Hb), ZnO nanoparticles (nano‐ZnO) and ionic liquid 1‐butyl‐3‐methylimidazolium hexafluorophosphate (BMIMPF₆) was fabricated and further modified on the glassy carbon electrode (GCE). The electrochemical behaviours of Hb in the composite film were carefully studied and a pair of quasi‐reversible redox peaks appeared in pH 7.0 phosphate buffer solution, which was attributed to the electrode reaction of Hb heme Fe(III)/Fe(II) redox couple. The presences of nano‐ZnO and BMIMPF₆ in the film can retain the bioactivity of Hb and greatly enhance the direct electron transfer of Hb. The immobilized Hb showed high stability and good electrocatalytic ability to the reduction of hydrogen peroxide and O₂.