生物活性分子的拉曼光谱电化学研究(英文)

本文概述了采用电化学现场拉曼光谱技术研究氧化物歧化酶在L 半胱氨酸修饰金电极表面的电子迁移反应以及腺嘌呤共存条件下超氧化物歧化酶在金电极表面的电子迁移反应和不同电位下银电极表面烟酰胺腺嘌呤二核苷酸的吸附等体系的反应吸附特性 .所得结果对于分析和研究生物活性分子电化学过程机理具有重要意义 .     

EQCM技术对电子传递促进机制的研究

本文报道了腺嘌呤存在时对超氧化物歧化酶在金丝电极上电化学行为的影响。并从电化学石英晶体微天平技术的测量结果，初步讨论了腺嘌呤对促进超氧化物歧化酶电子传递过程的作用机制。     

聚腺嘌呤核苷酸在金电极上的吸附氧化

采用微电极循环伏安法和吸附转移溶出伏安法研究了单链多聚腺嘌呤核苷酸Poly(A)在金电极上的伏安行为。重点了考察了Poly(A)的吸附和氧化过程。发现Poly(A)分子在金电极表面能够形成多种状态的特性吸附。影响吸附态和吸附强度的主要因素是吸附电势, 吸附时间和溶液浓度。在负电位区, 随着吸附时间(t~s)的变化, Poly(A)分子在金电极表面发生不同状态的以腺嘌呤碱基为吸附位点的强吸附, 这种以腺嘌呤碱基吸附的Poly(A)分子能够在零伏附近给出很强的氧化电流峰和对应的还原峰。     

聚腺嘌呤核苷酸在金电极上的吸附氧化

采用微电极循环伏安法和吸附转移溶出伏安法研究了单链多聚腺瞟吟核苷酸Poly(A)在金电极上的伏安行为.重点考察了Poly(A)的吸附和氧化过程.发现Poly(A)分子在金电极表面能够形成多种状态的特性吸附.影响吸附态和吸附强度的主要因素是吸附电势,吸附时间和溶液浓度.在负电位区,随着吸附时间(T_s)的变化,Poly(A)分子在金电极表面发生不同状态的以腺嘌呤碱基为吸附位点的强吸附,这种以腺嘌呤碱基吸附的Poly(A)分子能够在零伏附近给出很强的氧化电流峰和对应的还原峰.     

电化学石英晶体微天平应用研究和背景扣除

基于用循环伏安法研究非理想可逆体系时,电极本身的氧化峰电量与还原峰电量存在一比值。据此建立了一种用于电化学石英晶体微天平应用研究的背景扣除新方法。用这种方法研究了腺嘌呤、腺苷、腺苷一磷酸在金电极上的电化学氧化行为。结果表明:3种活性分子均能在1.2V左右氧化,对应的氧化电流大小顺序为:腺嘌呤>腺苷>腺苷一磷酸,氧化过程的电子转移数为6。     

电化学预处理玻碳电极微分计时电位溶出法测定DNA中的嘌呤碱基及DNA浓度

研究了鸟嘌呤(G)、腺嘌呤(A)、鸟嘌呤核苷、腺嘌呤核苷和变性DNA在电化学预处理玻碳电极上的恒电流微分计时电位溶出行为. 实验结果表明, 用电化学方法预处理玻碳电极操作简单, 效果明显, 预处理玻碳电极对嘌呤及其核苷和DNA的吸附能力大大增强, 用微分计时电位溶出法可以得到灵敏的溶出峰, 溶出峰高(dt/dE)与其浓度在一定范围内呈良好的线性关系, 可用于嘌呤碱基及其核苷的定量检测和DNA浓度的测定. 将该方法应用于酸变性DNA样品中鸟嘌呤与腺嘌呤的同时测定, 选择性好、灵敏度高; 还可获得有关DNA损伤的一些信息.     

金电极上偶氮腺嘌呤的电化学行为研究

本文研究了光滑金电极上偶氮腺嘌呤的电化学特性,并确定了相关动力学参数. 在含偶氮腺嘌呤的0.2 mol·L^-1的磷酸盐缓冲液(PBS,pH = 4.0 ~ 10.0）中,发现其循环伏安图上出现一对氧化还原峰. 基于对扫速和伏安峰值电位的分析,结果表明这是一个由吸附控制的可逆偶氮腺嘌呤氧化还原电化学过程. 当pH值从低到高改变时,氧化还原峰值向负电位移动,证实H⁺参与了该反应. 通过进一步实验数据分析和电极表面吸附量计算,发现该反应为分步进行的两电子两质子反应. 最后,通过快速循环伏安扫描方法确定了电化学过程的表观传递系数α和表观速率常数ks.     

超氧化物歧化酶在纳米金/L-半胱氨酸修饰金电极上的电化学行为

通过L-半胱氨酸将纳米金修饰到金电极上,把超氧化物歧化酶(SOD)固定在修饰电极表面,制备了SOD-纳米金/L-半胱氨酸修饰电极。运用交流阻抗法、循环伏安法等方法表征了该电极,发现SOD在该电极上于0.15V和-0.05V左右产生较明显的氧化还原峰,在0.04～0.24V/s扫描速率范围内,其还原峰电流与扫描速速呈线性关系,表明该电极过程受吸附控制。研究了H2O2对SOD-纳米金/L-半胱氨酸修饰电极伏安行为的影响,发现该电极的还原峰电流与H2O2浓度在1.0×10-6～2.0×10-4mol/L范围内呈良好的线性关系,相关系数为-0.996,可用于对H2O2的分析检测。     

双层纳米金修饰电极对多巴胺的测定及应用研究

利用含有连续腺嘌呤碱基模块的DNA(CA DNA)构建了双层纳米金,在此基础上制备了由聚番红花红和双层三维分布的纳米金修饰的玻碳电极,并研究了多巴胺(DA)在此修饰电极上的电化学行为,发现对于DA的氧化,CA DNA构建的电极比巯基DNA构建的电极能够起到更明显的电催化作用。利用差分脉冲法(DPV)考察了DA测定的优化条件,并发现其浓度在8.0×10-9~1.2×10-6mol·L-1范围内与氧化峰电流呈良好的线性关系。该电极用于实际样品的测定,结果满意。     

基于铁氰化钐修饰的玻碳电极研究鸟嘌呤和腺嘌呤的电化学行为及其含量的测定

利用电化学沉积法将铁氰化钐沉积在玻碳电极表面,形成铁氰化钐修饰电极,并利用循环伏安法研究了鸟嘌呤和腺嘌呤在该修饰电极上的电化学行为。相比裸玻碳电极,鸟嘌呤和腺嘌呤在修饰电极上的氧化峰电流增大,氧化峰电位降低,说明该修饰电极对鸟嘌呤和腺嘌呤的氧化具有良好的电催化能力。在优化条件下,两者的氧化峰电流与其浓度在5.0~70μmol·L-1范围内呈现线性关系,检出限(3S/N)均为1.0μmol·L-1。     

Study on the direct electron transfer process of superoxide dismutase

The electron transfer process of biological important species, superoxide dismutase (SOD), was studied using cyclic voltammetric method at different conditions. The rate of electron transfer process of SOD at conventional bare gold electrode was very low. Different methods were used to enhance the rate of this process. Gold microdisk electrode and gold minigrid electrode were used to replace the used conventional size gold electrode and the electron transfer rate was enhanced obviously. Different promoters, such as bis(4-pyridyl)disulfide, histidine and arginine, were used to promote the electron transfer process also. Promising results were observed with the help of those promoters. The rate enhancement through the participation of amino acids might be more interesting for the exploration of the real process of SOD-related reaction inside the human body.     

The electrochemical and spectroelectrochemical behaviors of SOD at cysteine modified gold electrode.

Different promoters were used to enhance the rate of the electron transfer process of superoxide dismutase (SOD). A quasi-reversible cyclic voltammogram (CV) of SOD was observed on the cysteine-modified gold wire electrode. The coupled adsorption/desorption processes and the characteristic Raman spectra of different states of SOD molecules on the electrode surface were studied with electrochemical quartz crystal microbalance (EQCM) and in-situ Raman spectroelectrochemical techniques. The possible promotion mechanism was discussed.     

DNA Hydrolysis and Voltammetric Determination of Guanine and Adenine Using Different Electrodes

Abstract

This work reports the development of a biosensor method for the label‐free detection of specific DNA sequences. In the initial phase, square wave voltammetry (SWV) was used in a comparative investigation into the electrochemical oxidation of purines (guanine and adenine) and DNA fragments at various electrode surfaces: carbon paste (CPE), glassy carbon electrode (GCE), and gold (AuE). Relative to the carbon electrodes, an approximate 4.0‐fold, 6.0‐fold, and 3.25‐fold increase in the anodic response was observed when guanine, adenine, and hydrolyzed DNA, respectively, were measured on the AuE. It was shown that the guanine and adenine bases could be successfully determined by use of SWV for a deoxyribonucleic acid sample following acid hydrolysis. This label‐free detection of hydrolyzed DNA on gold electrodes has significant advantages over methods using existing carbon electrode materials because of its higher sensitivity and the potential applicability of microfabrication techniques for the production of the requisite gold electrodes.

In another phase of development, the times and conditions for DNA hydrolysis and purine release were investigated. It was shown that under optimal conditions, trace levels of the purine bases could be readily detected following 20 min of hydrolysis at room temperature. The proposed method can be used to estimate the guanine and adenine contents in DNA with in a linear range of 5–30 ng ml^?1.

Finally, when appropriate probe sequences were first adsorbed on the surface of the screen‐printed gold electrode (SPGE), this electrochemical biosensor could be used to specifically detect sequences from ss corona virus aviair following hybridization and hydrolysis reactions on the sensor surface. No enhancement of the voltammetric response was observed when the sensor was challenged with a non‐complementary DNA sequence.     

超氧化物歧化酶催化-电化学调控的原子转移自由基聚合方法制备分子印迹聚合物

病理学中对含金属蛋白质的敏感检测极其重要。 本文以超氧化物歧化酶(SOD)作为金属蛋白,SOD既作为模板分子又作为催化剂进行电化学调控的原子转移自由基聚合(eATRP)反应制备蛋白质印迹聚合物(PIPs),用于SOD电化学生物传感器。 该方法不需要过渡金属离子,具有制备简单、节约试剂、保护环境等优点。 我们选用L-半胱氨酸和纳米金修饰的金电极(Au/L-cys/nanoAu)作为工作电极将氧化型SOD催化还原为还原型SOD,利用还原型SOD的Cu(Ⅰ)粒子,在引发剂4-硫苯基-2-溴-2-甲基丙酸酯(4-mercaptophenyl 2-bromo-2-methylpropanoate,4-HTP-Br)修饰的金电极上调控丙烯酰胺、N,N-亚甲基双丙烯酰胺的eATRP聚合制备SOD PIPs。 利用循环伏安法(CV)和X射线光电子能谱(XPS)方法对其进行了表征。 通过微分脉冲伏安法(DPV),在最优的条件下利用此修饰电极对溶液中的SOD进行检测,线性响应范围为1.0×10^-7~1.0×10² mg/L,检测限为6.8×10^-8 mg/L(S/N=3),相关系数为0.995。 与其它检测SOD的方法相比,该方法具有更宽的线性范围和较低的检测限。 本研究对于制备PIPs,用蛋白质催化的eATRP和含金属蛋白的敏感检测均有重要意义。     

Electrochemical properties of Nile Blue covalently immobilized on self-assembled thiol-monolayer modified gold electrodes.

A monolayer of Nile Blue (NB) has been covalently immobilized on the self-assembled thiol-monolayer modified gold electrode. Cyclic voltammograms indicated a stable and reverse redox process of NB bonded on the electrode surface. The mechanisms of redox process coupling with proton transfer were proposed. The NB-modified electrode showed excellent electrocatalytic activity toward Nicotinamide adenine dinucleotide (NADH) oxidation and horseradish peroxidase (HRP) reduction. A hydrogen peroxide biosensor based on NB as a mediator has been demonstrated.     

480—Redox and adsorption behaviour of some redox coenzymes involved in an electron-transport chain studied by the electro-optical technique

The redox and adsorption behaviour of some redox coenzymes involved in an electron-transport chain, i.e. ubiquinone-10 (CoQ), flavocoenzymes [flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD)] and nicotinamide adenine dinucleotide (NAD⁺), has been studied at a gold electrode by cyclic voltammetry and specular reflectivity measurement. All the coenzymes investigated were found to participate in electron transport in adsorbed states on the electrode surface. Adsorbed CoQ and flavocoenzymes are reduced and the resulting products remain adsorbed at the surface. Contrary to them, adsorbed NAD⁺ is reduced and then desorbed immediately. Possible models for the surface orientation of adsorbed molecules were proposed based on the experimental data.Some analogies can be noted between the interfacial behaviour of these coenzymes at the electrode and that in mitochondria.     

SOD-PVP/Au电极的电化学行为及对H_2O_2的电催化

以聚乙烯吡咯烷酮K30为电催化剂,羧甲基纤维素为膜固定剂,将超氧化物歧化酶固定在电极上,制备了SOD-PVP/Au修饰电极.采用循环伏安法研究了该修饰电极的电化学行为,在pH7.0 PBS缓冲溶液中于0.305V和0.111V处出现一对明显的氧化还原峰,电极反应是一个受扩散控制的准可逆过程,扩散系数4.71×10~(-7)cm~2/s、异相电子迁移常数5.37×10~(-6)cm/s.修饰电极能够催化H_2O_2的电还原,还原峰电流与H_2O_2浓度在2.0×10~(-6)～2.0×10~(-4)mol/L范围呈线性关系,相关系数R=-0.99042,可用于H_2O_2的电催化检测.     

A superoxide dismutase-modified electrode that detects superoxide ion

A superoxide dismutase (SOD)-modified electrode, in which SOD is oriented on the gold electrode via a self-assembled monolayer of cysteine so as to allow its direct electrode reaction, possesses a bi-directional electrocatalysis for both the oxidation of superoxide ion (O2-) to O2 and the reduction of O2- to H2O2 and functions as a third generation O2- biosensor.     

Study of the immobilization of alcohol dehydrogenase on Au-colloid modified gold electrode by piezoelectric quartz crystal sensor,cyclic voltammetry,and electrochemical impedance techniques

The immobilization of alcohol dehydrogenase (ADH) on Au-colloid modified gold electrodes has been investigated. Colloidal Au was first self-assembled onto gold electrodes through the thiol groups of an 1,6-hexanedithiol monolayer. Piezoelectric quartz crystal sensor, cyclic voltammetry, and electrochemical impedance techniques were used to investigate the immobilization of ADH on Au colloids. The cyclic voltammogram tends to be more irreversible with increased ADH concentration. In the impedance spectroscopic study, an obvious difference of the electron transfer resistance between the Au-colloid modified electrode and the bare gold electrode was observed. Using the piezoelectric quartz crystal sensor, the Michaelis constant, K(m), and the maximum initial rate, V(max), of the immobilized ADH were estimated as 6.03 x 10(-4) M and 0.63 Hzs (-1), respectively. The binding constant of ADH with nicotinamide adenine dinucleotide (NAD) was also determined as 1.87 x 10(4) M(-1). Experimental results showed that colloidal Au can be used as a biocompatible matrix for enzyme immobilization.