金复合介孔SBA-15吸附血红蛋白在H2O2电催化反应中的应用

以P123嵌段共聚物表面活性剂为模板剂制备介孔氧化硅SBA-15,并用沉积-沉淀(DP)法在SBA-15介孔表面负载纳米Au颗粒制备得到金复合介孔SBA-15材料(Au-SBA-15).再以Au-SBA-15材料制备玻碳修饰电极,将血红蛋白固定于修饰电极上用循环伏安法考察其对不同浓度H₂O₂溶液的电催化反应.在固定了血红蛋白的Hb/Au-SBA-15/GC修饰电极上,H₂O₂在+0.95 V处出现了氧化峰,且随着H₂O₂浓度的增大峰电流不断增加,说明金复合介孔氧化硅材料具有良好的生物兼容性,有利于血红蛋白的固定,其修饰电极对H₂O₂溶液具有一定的电催化作用.     

磁性印迹纳米粒子固定血红蛋白修饰磁性电极构建过氧化氢传感器

采用表面印迹技术,以磁性二氧化硅纳米粒子（Fe₃O₄@SiO₂ NPs）作为载体、血红蛋白（Hb）为模板分子、正硅酸乙酯（TEOS）为印迹聚合物单体,制备了Hb印迹Fe₃O₄@SiO₂的磁性印迹纳米粒子（MMIPs NPs）. MMIPs NPs具有磁性内核和血红蛋白印迹壳层的核壳结构,可以富集并固定Hb. 使用壳聚糖将MMIPs NPs固定于磁性电极表面,构建血红蛋白类酶生物传感器,研究了Hb对过氧化氢（H₂O₂）的催化活性. MMIPS NPS相比于磁性非印迹纳米粒子（MNIPS NPS）,催化电流增加了14.3%. 采用磁性电极,MMIPS NPS、Hb和O₂的顺磁性使得该类酶生物传感器对H₂O₂的催化电流增加了60.0%. 血红蛋白类酶生物传感器电流响应与H₂O₂浓度在25 ~ 200 μmol·L^-1间呈线性关系,检出限为3 μmol·L^-1（S/N=3）,表明该类酶传感器对H₂O₂具有良好的催化性能.     

酞菁钴及其衍生物修饰电极对分子氧的电催化还原

在玻碳电极上采用吸附法制备了四溴代酞菁钴(CoPcBr₄)、酞菁钴(CoPc)和四-α-(2,2,4-三甲基-3-戊氧基)酞菁钴(CoPc(OC₈H₁₇)₄)修饰电极。利用循环伏安法和线性扫描伏安法研究了修饰电极在酸性介质中对分子氧的电催化还原,比较了不同取代基的酞菁钴对电催化性质的影响。结果表明,它们对分子氧还原均具有良好的电催化活性,其中酞菁钴和四-α-(2,2,4-三甲基-3-戊氧基)酞菁钴对O₂的催化是2电子还原生成H₂O₂,与裸电极相比,O₂的还原峰电位分别向正方向移动了0.33和0.48 V。而四溴代酞菁钴修饰电极在-0.1和-0.7 V附近产生的2个还原峰,说明它催化O₂到H₂O₂的还原以后还可以促进H₂O₂继续还原到H₂O,最终实现O₂的4电子还原。     

碳糊电极上无机膜固载血红蛋白的直接电化学

报道了用硅溶胶-凝胶(Sol-gel)膜将血红蛋白(Hb)固载于碳糊电极上的直接电化学行为.研究结果表明,Hb-Sol-gel修饰的碳糊电极在pH=7.0的缓冲溶液中于-0.275V(vs.Ag/AgCl)处有一对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.HbFe(Ⅲ)/Fe(Ⅱ)电对的式量电位在pH5.0～11.0范围内与溶液pH值呈线性关系,表明Hb的电化学还原很可能是一个质子伴随着一个电子的电极过程.FTIR光谱证实,Sol-gel膜对Hb的固载没有破坏其天然结构.Hb-Sol-gel修饰的碳糊电极能够催化还原H₂O₂,可望将其用于制作第三代生物传感器.     

基于贵金属纳米颗粒构建无酶过氧化氢电化学传感器的研究

采用一步电化学沉积方法分别将三种常用贵金属纳米颗粒(Au,Ag,Pt)负载于工作电极上,构建了基于纳米薄膜的过氧化氢(H₂O₂)无酶电化学传感器。通过扫描电子显微镜(SEM)表征证明三种金属纳米颗粒成功修饰在玻碳电极(GCE)表面。通过比较三种金属纳米颗粒检测H₂O₂的能力,发现Ag纳米粒子具有更优异的催化活性。进一步研究扫描速率和检测电压对Ag/GCE催化性能的影响。电化学实验结果表明,该修饰电极显示出优异的H₂O₂催化活性以及在优化条件下可以达到0.01～23mmol·L^-1的线性范围,检出限为3.3μmol·L^-1,并将该传感器用于检测吐温80中残留H₂O₂,为吐温80的质量检查提供了一种简单快捷的方法。     

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。     

基于CdSe@CdS/壳聚糖/gC3N4复合物的卡那霉素电化学发光适配体传感器

利用核壳型的CdSe@CdS量子点作为发光物质,并用壳聚糖(CS)、类石墨烯氮化碳(gC₃N₄)与CdSe@CdS量子点合成了CdSe@CdS/CS/gC₃N₄复合物,将该复合物修饰至玻碳电极(GCE)表面,将适配体(Apt)的互补DNA链(cDNA)通过化学反应连接到量子点上,Apt与cDNA发生杂交反应而被修饰至电极表面。将辣根过氧化物酶(HRP)固定到该修饰电极表面,构建了检测卡那霉素(Kana)的电化学发光(ECL)适配体传感器。通过生物催化沉淀(BCP)方法实现Kana的检测,溶液中无Kana时,在H₂O₂的存在下,修饰在电极上的HRP可以催化氧化4-氯-1-萘酚(4-CN),在电极表面产生不导电的苯并-4-氯己二烯酮沉淀,导致电化学发光信号明显降低。溶液中存在Kana时,Kana会与Apt特异性结合,部分dsDNA解旋,导致部分HRP从电极表面脱落,BCP反应减弱,导致ECL信号增强,实现目标物质的特异性检测。计算适配体传感器在Kana溶液中的...     

Mn/Ce-ZrO2催化剂低温NH3-SCR脱硝性能研究

采用浸渍法制备了三种具有不同载体的锰基NH₃低温选择性催化还原(NH₃-SCR)催化剂Mn/Ce-ZrO₂、Mn/P₂₅和Mn/Al₂O₃。研究了三种催化剂低温SCR脱硝活性及抗H₂O、抗SO₂性能,并采用XRD、NH₃-TPD和H₂-TPR手段对催化剂的物理化学性质进行表征。结果表明,在无H₂O和SO₂存在的情况下,三种催化剂的低温SCR催化活性均比较高。相对来说,Mn/Ce-ZrO₂在低温段(100~160℃)活性更高,Mn/P₂₅在高温段(160~220℃)活性更高,这与两种催化剂的氧化还原性质有关。H₂-TPR表征表明,Mn/Ce-ZrO₂更容易发生氧化还原反应,而Mn/P₂₅还原峰对应的温度较高、面积较大。三种催化剂均有很高的低温抗水性能。另外,Mn/Ce-ZrO₂的抗H₂O、抗SO₂性能最好,而Mn/P₂₅的抗H₂O、抗SO₂性能最差。Mn/Ce-ZrO₂具有较好的抗H₂O、抗SO₂性能是由于其具有较多的表面酸位点,且表面生成的硫铵盐不稳定。     

Au单晶电极上H2O2的氧化反应研究

本文利用旋转圆盘电极系统研究了酸性介质中H₂O₂在Au(100)和Au(111)电极表面的电化学行为. 实验发现在Au电极上H₂O₂难以发生还原,但是当电位稍微正于H₂O₂氧化为O₂的平衡电势时即可发生氧化. 在Au(111)上H₂O₂氧化的起始电位比在Au(100)正0.1 V左右. Au(100)上的双桥位位点能增强反应中间体*OOH的吸附,可能是导致Au(100)上H₂O₂氧化反应超电势比Au(111)低的主要原因. 在较正电位区(E>1.2 V), 当电极表面被氧物种覆盖时,H₂O₂在两个电极上的氧化都会受到一定程度的抑制,这种影响在Au(111)上比Au(100)上更加明显,这与Au(111)上氧物种的生成与逆向还原可逆性差的趋势一致. 最后还将Au与Pt单晶电极上H₂O₂氧化的行为进行了对比分析.     

血红蛋白在二氧化铈修饰电极上的直接电化学

将二氧化铈(CeO₂)与酶复合修饰电极, 采用循环伏安法研究了血红蛋白(Hb)在CeO₂修饰的玻碳电极上的电化学行为. 实验表明, 固定在CeO₂材料上的Hb, 不仅能有效地与电极表面进行直接电子转移, 而且能够保持其生物催化活性. 制得的Nafion/CeO₂/Hb/GC修饰电极的电子传递速率k_s为(0.68±0.09) s^－1, 对H₂O₂的检测限为1.013 μmol•L^－1, 重现性和稳定性较好. CeO₂在实验中体现出一定的生物相容性, 起到了促进Hb与电极之间进行直接电子传递的作用. CeO₂修饰电极进行蛋白质直接电化学测定以及酶生物电催化的成功实践, 为稀土氧化物材料在电化学传感领域中的应用开辟了思路.     

Carbonized Hemoglobin Nanofibers for Enhanced H2O2 Detection

Electrospun hemoglobin (Hb) microbelts were used as a novel precursor to produce a new class of carbon nanofibers (Hb‐CNFs) containing Fe species (Fe₂O₃ and/or Fe‐N₄ moiety). The Hb‐CNFs modified glassy carbon electrode (Hb‐CNFs/GCE) exhibits significant oxidation/reduction towards H₂O₂. The observed H₂O₂ oxidation/reduction starting at ca. +0.26 V and +0.15 V (vs. Ag/AgCl) are significantly lower than the values observed at other CNFs modified GCE. The Hb‐CNFs/GCE was also applied to the amperometric detection of H₂O₂ and the results showed fast response, high sensitivity, excellent reproducibility, good selectivity, and wide dynamic range with good limit of detection.     

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.     

Direct Electrochemistry and Electrocatalysis of Hemoglobin in Lipid Film Incorporated with Room‐Temperature Ionic Liquid

A facile phospholipid/room‐temperature ionic liquid (RTIL) composite material based on dimyristoylphosphatidylcholine (DMPC) and 1‐butyl‐3‐methylimidazolium hexafluorophosphate ([bmim]PF₆) was exploited as a new matrix for immobilizing protein. Cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) were adopted to characterize this composite film. Hemoglobin (Hb) was chosen as a model protein to investigate the composite system. UV‐vis absorbance spectra showed that Hb still maintained its heme crevice integrity in this composite film. By virtue of the Hb/DMPC/[bmim]PF₆ composite film‐modified glassy carbon electrode (GCE), a pair of well‐defined redox peaks of Hb was obtained through the direct electron transfer between protein and underlying GCE. Moreover, the reduction of O₂ and H₂O₂ at the Hb/DMPC/[bmim]PF₆ composite film‐modified GCE was dramatically enhanced.     

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.     

金复合介孔SBA-15吸附血红蛋白在H2O2电催化反应中的应用

以P123嵌段共聚物表面活性剂为模板剂制备介孔氧化硅SBA-15,并用沉积-沉淀(DP)法在SBA-15介孔表面负载纳米Au颗粒制备得到金复合介孔SBA-15材料(Au-SBA-15).再以Au-SBA-15材料制备玻碳修饰电极,将血红蛋白固定于修饰电极上用循环伏安法考察其对不同浓度H2O2溶液的电催化反应.在固定了血红蛋白的Hb/Au-SBA-15/GC修饰电极上,H2O2在+0.95 V处出现了氧化峰,且随着H2O2浓度的增大峰电流不断增加,说明金复合介孔氧化硅材料具有良好的生物兼容性,有利于血红蛋白的固定,其修饰电极对H2O2溶液具有一定的电催化作用.     

Direct electrochemistry of hemoglobin on graphene/Fe3O4 nanocomposite-modified glass carbon electrode and its sensitive detection for hydrogen peroxide

Graphene/Fe₃O₄ nanocomposite was prepared for the immobilization of hemoglobin (Hb) to improve the electron transfer between Hb and glass carbon electrode (GCE). The characterization of nanocomposites was described by transmission electron microscopy, Fourier transform infrared, Raman spectroscopy, and X-ray photoelectron spectroscopy, respectively. The electrochemistry of Hb on the graphene/Fe₃O₄-based GCE was investigated by cyclic voltammetry and amperometric measurement. The modified electrode showed a wide linear range from 0.25 μmol/L to 1.7 mmol/L with a correlation coefficient of 0.9967. The detection limit of the H₂O₂ biosensor was estimated at 6.0?×?10^?6?mol/L at a signal-to-noise ratio of 3.     

Voltammetric Behavior of Antileukemia Drug Glivec. Part I – Electrochemical Study of Glivec

The electrochemical behavior of the antileukemia drug glivec was investigated at a glassy carbon electrode (GCE). The oxidation is a complex, pH‐dependent, irreversible electrode process involving the transfer of 2 electrons and 2 protons and the formation of an electroactive product, P_glivec, which strongly adsorbs on the GCE surface and undergoes reversible oxidation. The adsorption of P_glivec at the GCE surface yields a compact monolayer that inhibits further oxidation of glivec. The electrochemical reduction is a simple pH dependent irreversible process involving the transfer of 2 electrons and 2 protons and occurs with the formation of a nonelectroactive product. The diffusion coefficient of glivec was calculated to be D_O=7.35×10^?6 cm² s^?1 in pH 4.5 0.1 M acetate buffer.     

Cu3Mo2O9 nanosheet incorporated with hemoglobin on carbon ionic liquid electrode for the direct electrochemistry and electrocatalysis

In this paper Cu₃Mo₂O₉ nanosheet was prepared by a hydrothermal method and further used to investigate the direct electrochemistry of hemoglobin (Hb) with a carbon ionic liquid electrode (CILE) as the substrate electrode. Hb was mixed with Cu₃Mo₂O₉ nanosheet and cast on the CILE surface with chitosan (CTS) as the film-forming material. UV-vis and FT-IR spectroscopic results showed that Hb remained in its native structure in the composite film. Direct electron transfer of Hb on the modified electrode was realized with a pair of well-defined quasi-reversible redox waves that appeared on cyclic voltammograms. The redox peak potential appeared at ?0.252 V (E _pc) and ?0.141 V (E _pa), respectively, with the formal peak potential calculated as ?0.196 V, which was the characteristic of electroactive center of Hb heme Fe(III)/Fe(II). The result could be attributed to the presence of Cu₃Mo₂O₉ nanosheet on the electrode surface that was of benefit for the protein orientation and promoted direct electron transfer between the redox active center of Hb and the substrate electrode. The CTS/Cu₃Mo₂O₉–Hb/CILE showed good electrocatalytic ability in reducing different substrates such as trichloroacetic acid, H₂O₂ and O₂, with wider linear range and lower detection limit, thus exhibiting the potential application of the Cu₃Mo₂O₉ nanosheet in third-generation electrochemical biosensors.     

Gold Nanoparticles-electrochemically Reduced Graphene Oxide/Poly(indole-5-carboxylic acid) Nanocomposite for Electrochemical Non-enzymatic Sensing of Hydrogen Peroxide

Herein, co-electrodeposition of AuNPs and ERGO onto GCE was conducted to prepare the modified electrode, GCE/AuNPs-ERGO. The poly(indole-5-carboxylic acid) (P(In-5-COOH) was then coated onto the GCE/AuNPs-ERGO with the help of electropolymerization. FT-IR, FE-SEM and EDX, and XRD techniques were employed to characterize the prepared nanocomposite. The nanocomposite modified electrode (GCE/AuNPs-ERGO/P(In-5-COOH)) was examined for the electrochemical reduction of H₂O₂ using chronoamperometry. A high reduction current for H₂O₂ was observed due to the synergistic effect between AuNPs-ERGO and P(In-5-COOH). The proposed sensor demonstrated a wide linear range of 0.025–750 μmol L⁻¹, with a LOD of 0.008 μmol L⁻¹ at −0.4 V. Furthermore, the developed sensor was applied for the detection of H₂O₂ in fetal bovine serum and urine samples.     

Simultaneous Electroanalysis of Hypochlorite and H2O2: Use of I−/I2 as a Probing Potential Buffer

Sodium hypochlorite (NaClO) and hydrogen peroxide (H₂O₂) have been simultaneously analyzed, for the first time, using a simple and rapid potentiometric method. The present method shows a high sensitivity, selectivity and satisfactory reproducibility. Pt electrode was used as an indicator electrode and the I₂/I^? redox couple was used as a probing potential buffer. The large difference in the rates of the oxidation of I^? by the two oxidizing agents, that is, the oxidation of I^? by NaClO is by several orders of magnitude faster than that by H₂O₂, enabled the selective analysis of these two species. Based on such a large difference in the rates, a momentary potential response corresponding to the oxidation of I^? by NaClO and another quite slow one by H₂O₂ could be obtained. Factors affecting the selectivity as well as the sensitivity, such as the concentrations of molybdate (used as catalyst for the oxidation of I^? by H₂O₂), H⁺, I₂, and I^? in the potential buffer were examined. The expected Nernstian responses were obtained over a considerable range of the concentrations of the two oxidizing agents with slopes of 30.5 and 29.9 mV for NaClO and H₂O₂, respectively (in a close agreement with the theoretical value, that is, 29.6 mV) and with a detection limit in the submicromolar range (0.2 μM).