石墨烯-纳米金复合物修饰电极用于异烟肼及抗坏血酸的同时测定

制备了石墨烯-纳米金(GR/Au)复合物修饰的玻碳电极,并将其用于异烟肼(INZ)和抗坏血酸(AA)的同时检测。在0.1 mol·L-1PBS(pH 3.5)缓冲溶液中,采用循环伏安法分别考察了INZ及AA的电化学行为。结果显示,INZ及AA的氧化峰电流均与扫速(50~300 mV·s-1)的平方根呈良好线性关系,且复合物修饰电极对INZ及AA的氧化显示出高的催化性能,二者之间产生明显的峰分离(ΔV=170 mV)。在最优实验条件下,当AA存在时,INZ的氧化峰电流与其浓度在3.0×10-6~1.5×10-4mol·L-1范围内呈良好的线性关系,其检出限为8.0×10-7mol·L-1。而当INZ存在时,AA的氧化峰电流与其浓度在3.0×10-5~1.0×10-3mol·L-1范围内呈良好的线性关系,其检出限为6.0×10-6mol·L-1。将此修饰电极用于药物中INZ及AA的测定,结果满意。     

间氨基苯酚修饰玻碳电极测定多巴胺

玻碳电极在含有2.0 mmol·L-1间氨基苯酚的0.1 mol·L-1的三水合高氯酸锂溶液中,于0～1.5 V的电位范围内进行电化学修饰,制备了间氨基苯酚修饰电极(m-AP/GCE).研究发现:间氨基苯酚修饰电极对多巴胺有良好的电催化作用,多巴胺在该电极上出现了一对氧化还原峰,相对于裸玻碳电极,氧化还原峰电位差为减至70 mV,提出了用循环伏安法测定多巴胺的方法.氧化峰电流与多巴胺的浓度在1.2×10-7～9.1×10-6和9.1×10-6～1.2×10-4mol·L-1范围内呈线生关系,检出限(3S/N)为3.2×10-8mol·L-1.     

用杯芳烃膜修饰碳纤维电极计时电流法测定过氧化氢

在含8.0×10-4mol·L-1杯芳烃的0.1 mol·L-1四丁基高氯酸铵溶液中,在-0.4～0.6 V电位下,在碳纤维电极表面电沉积一层杯芳烃膜,制得杯芳烃膜修饰碳纤维电极.采用扫描电镜和交流阻抗法对电极表面的性能进行了表征,采用循环伏安法和计时电流法对其电化学性能进行研究.试验发现:过氧化氢在杯芳烃膜修饰碳纤维电极上出现一个明显氧化峰,氧化峰电位为0.6 V,提出了用计时电流法测定过氧化氢的方法.在优化的试验条件下,氧化峰电流与过氧化氢的浓度在1.5×10-5～3.8×10-3mol·L-1范围内呈线性关系,检出限(3S/N)为5.0×10-6mol·L-1.修饰电极用于医用消毒水中过氧化氢的测定,所得结果与高锰酸钾滴定法测定值相一致,用标准加入法做回收率试验,所得结果在97%～104%之间,测定值的相对标准偏差(n=10)为4%.     

L-半胱氨酸在乙酰二茂铁修饰碳糊电极上的电催化氧化及其电化学动力学性质研究

研究了L-半胱氨酸(L-cysteine,L-Cys)在乙酰二茂铁(acetylferrocene,Afc)修饰碳糊电极(Afc/CPE)上的电催化行为.研究结果表明,Afc/CPE对L-Cys的电化学氧化具有良好的催化作用.用循环伏安法(CV)、计时电流法(CA)测定了L-Cys在Afc/CPE上的电极过程动力学参数.测得Afc分散于液体石蜡中表观扩散系数Dapp=9.49×10-9 cm-2·s-1,电荷传递系数α=0.59,电催化氧化反应速率常数k=(3.76±0.10)×103(mol·L-1)-1·s-1.催化氧化峰电流与L-Cys在浓度8.0×10-6～1.5×10-3mol·L-1范围内呈良好的线性关系,线性回归方程为Ipa(μA)=3.139 c(mmol·L-1) 4.068,r=0.999 7,检出限为2.5 μmol·L-1.该结果可用于对L-Cys的电化学定量测定.     

吸附镍(Ⅱ)的甘氨酸共价修饰玻碳电极的制备及应用于葡萄糖的无酶催化氧化测定

将玻碳电极(GCE)置于0.01 mol·L-1甘氨酸的[Bmin]PF6离子液体溶液中,于0~2.0 V电位间以50 mV·s-1扫描速率进行循环伏安扫描10圈,从而制成通过C-N共价键结合的甘氨酸修饰玻碳电极(Gly/GCE)。将此修饰电极置于0.1 mol·L-1氯化镍溶液中浸泡6 h,镍(Ⅱ)就吸附于甘氨酸修饰层上,制成了吸附着镍(Ⅱ)的Gly/GCE,记作Ni(Ⅱ)-Gly/GCE。此电极在0.1 mol·L-1氢氧化钠溶液中由于Ni2+/Ni3+电对的媒介作用对葡萄糖产生无酶催化氧化反应,导致在+0.55 V(vs.SCE)处氧化峰电流明显增高,电流响应值与葡萄糖浓度在1×10-6~2×10-3mol·L-1范围内呈线性关系,其检出限(3S/N)为3×10-7mol·L-1。据此,提出了测定葡萄糖的计时电流法,并应用于血清样品中葡萄糖的测定,所得结果与用Dimension RXL-MAX自动化分析仪的测定结果相符。     

氨基酸和金属分层修饰电极的制备及对麝香草酚的测定

用循环伏安法制备了不同类型的金属、氨基酸分层修饰电极,用阻抗谱对修饰电极进行了表征,以麝香草酚作为探针,研究了麝香草酚在不同修饰电极上的电化学行为。其中用银和L-苯丙氨酸分层修饰电极测定麝香草酚,峰电流最大。在最佳条件下,麝香草酚在银、L-苯丙氨酸分层修饰电极上产生一个明显的氧化峰,峰电位为:Epa=0.795 V,用循环伏安法进行测定时,峰电流与麝香草酚胺浓度在1.00×10~(-5)~1.00×10~(-3)mol·L~(-1)呈良好的线性关系,检出限为5.0×10~(-6)mol·L~(-1)。用差分脉冲法测定时,峰电流与麝香草酚浓度在7.50×10~(-6)~7.50×10~(-4)mol·L~(-1)呈良好的线性关系,检出限为8.0×10~(-7)mol·L~(-1)。该法用于药品中麝香草酚的测定,结果满意。     

循环伏安法研究利福平的电化学行为

采用循环伏安法研究了利福平在多壁碳纳米管修饰电极(MWCNT′s/GCE)上的电化学行为。结果表明:在pH 1.2的0.2mol.L-1硫酸-硫酸钠溶液中,修饰电极对利福平有良好的电催化作用,能够显著提高氧化还原峰电流,还原峰电流与利福平浓度分别在6.6×10-8～6.8×10-6 mol.L-1,6.8×10-6～4.8×10-5 mol.L-1范围内呈线性关系,检出限(3S/N)为3.0×10-8 mol.L-1。对利福平在修饰电极(MWCNT′s/GCE)上的电化学动力学性质进行了研究。     

吡虫啉在聚L-酪氨酸修饰电极上的电化学行为及其测定

采用循环伏安法研究了吡虫啉在制备的聚L-酪氨酸修饰电极上的电化学行为。结果表明,在pH 8.5的NH3.H2O-NH4C l缓冲溶液中,吡虫啉在聚L-酪氨酸修饰电极上的电化学行为是受扩散控制的不可逆电还原过程,转移电子数和质子数均为2,扩散系数D=5.15×10-5cm2.s-1。吡虫啉的还原峰电流与其浓度在5.0×10-7~8.0×10-5mol.L-1范围内呈良好的线性关系,线性方程为Ip(A)=2.435×10-6+0.809 5c(mol.L-1),r=0.998 6,检出限为2.36×10-7mol.L-1,样品测定回收率为94%~103%。     

盐酸左氧氟沙星在聚L-精氨酸/多壁碳纳米管修饰电极上的电化学行为

运用循环伏安法、线性扫描伏安法、计时电量法等研究了盐酸左氧氟沙星在聚L-精氨酸/多壁碳纳米管修饰电极上的电化学行为。实验表明:盐酸左氧氟沙星在聚L-精氨酸/多壁碳纳米管修饰电极上的电极反应过程为等电子等质子吸附控制的不可逆过程,在pH=6.0的Na2HPO4-NaH2PO4支持电解质中,其氧化峰电流与浓度在7.0×10-6~1.0×10-4mol·L-1范围内呈良好的线性关系,相关系数R为-0.9992,检出限为5.0×10-6mol·L-1,样品测定回收率为98.26%~101.70%。     

尿酸在石墨烯修饰玻碳电极上的电化学行为及测定

以抗坏血酸为还原剂,采用微波水热法化学还原氧化石墨烯合成了石墨烯纳米片,制备了石墨烯修饰的玻碳电极(RGO/GCE),并采用循环伏安法、计时电量法、交流阻抗法等电化学技术研究了尿酸在该修饰电极上的电化学行为及其影响因素。结果表明,在PBS缓冲溶液中,尿酸(UA)在石墨烯修饰电极上的电极反应是一个受扩散控制的不可逆氧化过程。电极反应的转移电子数n=2,有效面积A=0.182 cm2,扩散系数D=1.51×10-6 cm2.s-1。UA的氧化峰电流与其浓度在5.0×10-6～1.5×10-4 mol/L范围内呈良好线性,r=0.995 7。利用该RGO/GCE修饰电极可以快速准确地测定UA,检出限为2.7×10-7 mol/L,加标回收率为98%～100%。     

曲克芦丁在羧基化单壁碳纳米管修饰电极上的电化学氧化

研制了羧基化单壁碳纳米管修饰玻碳电极( SWCNTs - COOH/GCE).用交流阻抗谱法(EIS)和扫描电镜( SEM)研究了电极膜性能,应用循环伏安法(CV)考察了曲克芦丁在修饰电极上的电化学行为.结果表明,SWCNTs - COOH修饰电极对曲克芦丁的氧化有良好的电催化活性,其氧化反应为单电子单质子过程,结合恒...     

Sensitive detection of trifluoperazine using a poly-ABSA/SWNTs film-modified glassy carbon electrode

A poly-ABSA/SWNTs composite-modified electrode was fabricated by electropolymerizing aminobenzene sulphonic acid (ABSA) on the surface of glassy carbon electrode (GCE) modified with single-wall carbon nanotubes (SWNTs). SWNTs provide a 3D porous and conductive network for the polymer immobilization. The nanocomposite film was characterized by scanning electron microscope (SEM) and electrochemical impedance spectroscopy (EIS). The results indicated that this composite-modified electrode had strong electrocatalytic activity toward the oxidation of trifluoperazine (TFP). TFP could effectively accumulate on the modified electrode and generate a sensitive anodic peak at 0.72V (versus SCE) in pH 6.1 phosphate buffer solution. Under the selected conditions, the anodic peak current of TFP was linear with its concentration within the range from 1.0x10(-7) to 1.0x10(-5)molL(-1) and 1.0x10(-5) to 1.0x10(-4)molL(-1), and the detection limit was 1.0x10(-9)molL(-1) (S/N=3). This method was successfully applied to the detection of trifluoperazine in drug samples and the recovery was satisfactory. In comparison with the SWNTs/GCE or poly-ABSA/GCE prepared in the similar way, this composite-modified electrode exhibited better catalytic activity.     

A Novel Functionalized Single‐Wall Carbon Nanotube Modified Electrode and Its Application in Determination of Dopamine and Uric Acid in the Presence of High Concentrations of Ascorbic Acid

Multilayer films of negatively charged single‐wall carbon nanotubes (SWCNTs) and positively charged cetylpyridinium bromide (CPB) have been deposited on a glassy carbon electrode (GCE) using layer‐by‐layer (LBL) technique. The assembled multilayer films have been investigated by scanning electron microscopy (SEM), electrochemical impedance spectroscopy (EIS), and quartz crystal microbalance (QCM) measurements. The voltammetric signal of dopamine (DA), uric acid (UA), and ascorbic acid (AA) could be observed well‐separated with the assembled SWCNTs/CPB multilayer films in pH 7.0 PBS. The oxidation peak potentials of DA, UA, and AA are centered at about 169 mV, 292 mV and ?10 mV on differential pulse voltammograms (DPVs), respectively. The peak‐to‐peak potential separation was 123 mV, 179 mV, and 302 mV for DA‐UA, DA‐AA, and UA‐AA in DPVs, respectively. This permits the simultaneous detection of DA and UA in the presence of AA.     

DNA/聚(3,4-乙烯基二氧噻吩)修饰电极的制备及其用于亚硝酸根的电化学行为及测定研究

采用恒电流和电沉积两步法制备了脱氧核糖核酸-聚(3,4-乙烯基二氧噻吩)(DNA-PEDOT)复合膜修饰玻碳电极。用电化学阻抗法(EIS)和循环伏安法(CV)表征了不同修饰电极的修饰可行性和表面的电子传递能力。结果表明,DNA可以牢固地结合在PEDOT膜上,并能改善PEDOT膜的性质。研究了NO2-在DNA-PEDOT修饰电极上的电化学行为,提出了一种新的检测NO2-的电化学方法。在0.1 mol/L pH7.0的磷酸盐缓冲溶液(PBS)中,NO2-在DNA-PEDOT修饰电极上于0.88 V左右出现1个较好的氧化峰,考察了该氧化峰的性质及其影响因素。示差脉冲伏安法(DPV)的结果表明,NO2-的DPV氧化峰电流与其浓度在0.3~1.0、1.0~20、20~100μmol/L 3个范围内呈良好的线性关系,检出限(S/N=3)为60 nmol/L,并考察了可能存在的干扰物质对测定的影响。结果显示,该复合膜修饰电极对NO2-的检测具有良好的稳定性和选择性。将其用于实际样品的检测,结果满意。     

Enhanced Electrochemical Determination of Catechol and Hydroquinone Based on Pd Nanoparticles/Poly(Taurine) Modified Glassy Carbon Electrode

Here, Pd nanoparticles and poly(taurine) film was prepared on the glassy carbon electrode surface (Pd/Poly(TAU)/GCE) by the rapid electrochemical technique. The proposed composite surface was characterized by scanning electron microscopy(SEM), X‐ray photoelectron spectroscopy(XPS) and electrochemical impedance spectroscopy(EIS). Enhanced electron transfer ability and higher electroactive surface area were achieved at Pd/Poly(TAU)/GCE as compared to the bare GCE and polymer film electrode. The new and highly stable Pd/Poly(TAU)/GCE was employed for the individual and simultaneous determination of hydroquinone and catechol which were environmentally toxic. Under the optimized conditions, HQ and CC were individually determined by using the differantial pulse voltammetry in the linear ranges of 0.008–100 μM and 0.001–100 μM with the detection limits of (LOD) 2.1 nM and 0.68 nM, respectively. In case of simultaneous determination, LODs were found as 10 nM and 0.88 nM for HQ and CC, respectively. The content of both analytes in the real sample analysis was evaluated in the river water and tap water successfully.     

壳聚糖/多壁碳纳米管复合膜电化学手性识别色氨酸对映异构体

采用滴涂方式将羧酸化多壁碳纳米管(f-MWCNTs)修饰于玻碳电极(GCE)表面成膜,然后恒电位法在上述修饰电极表面电沉积壳聚糖(CS)膜,形成CS和f-MWCNTs复合膜修饰电极(CS/f-MWCNTs/GCE),并用于色氨酸(Trp)对映异构体的手性识别。采用扫描电子显微镜(SEM)表征了修饰电极表面形貌的差异,电化学阻抗(EIS)和循环伏安法(CV)研究修饰电极的电化学行为差异。差分脉冲伏安法(DPV)用于区别色氨酸(Trp)对映异构体,分离系数可达2.38。研究发现该修饰电极对L-Trp的DPV响应信号强于D-Trp,检测的线性范围为8.0×10~(-6)~4.0×10~(-3)mol/L,检出限(S/N=3)为5.0×10~(-6)mol/L。该方法简单、经济、快速,对发展其它手性化合物的检测方法提供了参考。     

Platinum Nanoparticles/Poly(isoleucine) Modified Glassy Carbon Electrode for the Simultaneous Determination of Hydroquinone and Catechol

A new electrochemical sensor based on Poly(Isoleucine) modified glassy carbon electrode decorated with platinum nanoparticles (Pt/Poly(Isoleucine)/GCE) was developed for sensitive individual and simultaneous determination of hydroquinone (HQ) and catechol (CC). Scanning electron microscopy (SEM), Electrochemical impedance spectroscopy (EIS), Cyclic voltammetry (CV) and Differential pulse voltammetry (DPV) were performed in order to characterize the Pt/Poly(Isoleucine)/GCE nanocomposite. For simultaneous determination of HQ and CC, Pt/Poly(Isoleucine)/GCE showed wide linear range between the 0.01–100.0 μM. The detection limits were 0.006 μM for HQ and 0.005 μM for CC. The Pt/Poly(Isoleucine)/GC electrode exhibited good sensitivity and reliability in the simultaneous electroanalysis of two isomers in PBS of pH 7.5. The modified electrode was used to detect the isomers in naturel samples.     

纳米金修饰玻碳电极对鸟嘌呤的催化氧化

采用电化学沉积法制备了纳米金修饰玻碳电极,并用循环伏安法和电化学阻抗法进行了表征,以此建立了一种直接测定鸟嘌呤的电分析方法。在磷酸盐缓冲溶液(pH 6.0)中,研究了鸟嘌呤在纳米金修饰电极上的电化学行为,实验结果表明,纳米金修饰电极可以增强鸟嘌呤在电极表面的吸附,并加快鸟嘌呤在电极表面的电子传输,使其电化学信号明显增大,检测灵敏度大大提高,该修饰电极对鸟嘌呤表现出良好的电催化性能。在优化实验条件下对鸟嘌呤进行测定,方法的线性范围为8.0×10-7~6.0×10-5mol/L,检出限为1.0×10-8mol/L,在鸟嘌呤浓度为1.0×10-5mol/L时测得RSD(n=10)为2.5%。     

Highly sensitive electrochemical determination of Sunset Yellow based on gold nanoparticles/graphene electrode

An electrochemical sensor was prepared using Au nanoparticles and reduced graphene successfully decorated on the glassy carbon electrode (Au/RGO/GCE) through an electrochemical method which was applied to detect Sunset Yellow (SY). The as-prepared electrode was characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM), atomic force microscopy (AFM) and electrochemical measurements. The results of cyclic voltammetry (CV) proved that Au/RGO/GCE had the highest catalytic activity for the oxidation of SY as compared with GCE, Au/GCE, and RGO/GCE. Differential pulse voltammetry (DPV) showed that the linear calibration curves for SY on Au/RGO/GCE in the range of 0.002 μM–109.14 μM, and the detection limit was estimated to be 2 nM (S/N = 3). These results suggested that the obtained Au/RGO/GCE was applied to detect SY with high sensitivity, low detection limit and good stability, which provided a promising future for the development of portable sensor in food additives.     

Sensitive determination of hydrazine using poly(phenolphthalein), Au nanoparticles and multiwalled carbon nanotubes modified glassy carbon electrode

This study reports a detailed analysis of an electrode material containing poly(phenolphthalein), carbon nanotubes and gold nanoparticles which shows superior catalytic effect towards to hydrazine oxidation in Britton–Robinson buffer (pH 10.0). Glassy carbon electrode was modified by electropolymerization of phenolphthalein (PP) monomer (poly(PP)/GCE) and the multiwalled carbon nanotubes (MWCNTs) was dropped on the surface. This modified surface was electrodeposited with gold nanoparticles (AuNPs/CNT/poly(PP)/GCE). The fabricated electrode was analysed the determination of hydrazine using cyclic voltammetry, linear sweep voltammetry and amperometry. The peak potential of hydrazine oxidation on bare GCE, poly(PP)/GCE, CNT/GCE, CNT/poly(PP)/GCE, and AuNPs/CNT/poly(PP)/GCE were observed at 596 mV, 342 mV, 320 mV, 313 mV, and 27 mV, respectively. A shift in the overpotential to more negative direction and an enhancement in the peak current indicated that the AuNPs/CNT/poly(PP)/GC electrode presented an efficient electrocatalytic activity toward oxidation of hydrazine. Modified electrodes were characterized with High-resolution transmission electron microscopy (HRTEM), scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS) and electrochemical impedance spectroscopy (EIS). Amperometric current responses in the low hydrazine concentration range of 0.25–13 µM at the AuNPs/CNT/poly(PP)/GCE. The limit of detection (LOD) value was obtained to be 0.083 µM. A modified electrode was applied to naturel samples for hydrazine determination.