利巴韦林原位聚合分子印迹电化学传感器的研制

利用原位聚合分子印迹技术,以3-氨基苯硼酸(3-ABBA)为功能单体,利巴韦林(RIB)为目标分子,以硼酸和顺式二醇在不同酸碱度条件下可逆形成环内酯键为原理,在玻碳电极表面原位聚合形成利巴韦林分子印迹膜,研制了测定利巴韦林的分子印迹电化学传感器。采用循环伏安法(CV)和差分脉冲法(DPV)对印迹膜性能进行研究。DPV测试表明:在最优实验条件下,利巴韦林的浓度在5.0×10~(-8)~1.0×10~(-5)mol/L范围内与峰电流呈良好的线性关系,相关系数(r~2)为0.995 3,检出限(S/N=3)为1.5×10~(-8)mol/L。特异性实验表明制备的传感器对利巴韦林的选择性良好。该分子印迹电化学传感器可用于食品中利巴韦林的检测。     

联苯胺分子印迹聚合物零流电位法传感器的制备及其应用

考察了在石墨烯修饰的铅笔芯电极( G-PEC)表面制备联苯胺分子印迹聚合物( BZ-MIP)的电聚合参数以及模板分子从印迹聚合物中去除的洗脱时间对BZ-MIP与BZ结合前后零流电位响应差值的影响,优化了最佳制备条件;计算出联苯胺及与其结构相近的4-氨基偶氮苯、4-氯苯胺、4-氨基联苯和单偶氮染料胭脂红在BZ-MIP上的印迹容量分别为0.632,0.1123,0.1123,0.0847和0.0725。实验结果表明,本方法制备的BZ-MIP对联苯胺特异识别性和选择性良好,其它物质不干扰模板分子与印迹聚合物印迹位点的结合。在联苯胺4伊10-8~1伊10-5 mol/L浓度范围内,BZ-MIP与BZ结合前后的零流电位差与其浓度对数呈正比,检出限为1.89伊10-8 mol/L,基于此制备出检测联苯胺的BZ-MIP-G-PEC零流电位传感器。应用此传感器检测实际样品,回收率为95.7%~104.2%。     

分子印迹聚合物传感器研究

分子印迹聚合物(molecular imprinting polymers,MIPs)是利用分子印迹技术合成的一种交联高聚物.分子印迹技术(molecular imprinting technique,MIT)是在近十几年来才发展起来的一门边缘科学技术.它结合了高分子化学、生物化学等学科,是模拟抗体-抗原相互作用的一种新技术,具有选择性识别位点的性质,作为传感器的理想敏感材料的制备方法日益受到研究者们的重视.本文综述了分子印迹技术的原理和分子印迹聚合物的制备方法,及其应用于传感器敏感材料的研究现状,并展望了其发展前景.     

基于氧化石墨烯增敏的聚邻苯二胺分子印迹电化学传感器测定多巴胺

本工作结合分子印迹技术和电化学检测方法对多巴胺(DA)进行了快速测定。以DA为模板分子,邻苯二胺(o-phenylenediamine,oPD)为功能单体,在氧化石墨烯(GO)修饰电极表面通过一步电聚合法制备分子印迹电化学传感器。采用透射电镜(TEM)和扫描电镜(SEM)对GO的形貌进行了表征,通过循环伏安法(CV)和差分脉冲伏安法(DPV)对传感器的电化学性能进行了分析。当DA的浓度在0.4～2000μmol·L^-1范围内时,DA在印迹电极上的DPV峰电流值与其浓度呈线性关系,检出限为8.0×10^-8 mol·L^-1;采用该方法对实际样品中的DA进行测定,回收率在92～108%之间。     

分子印迹电位型传感器快速检测猪尿液中的克伦特罗

以盐酸克伦特罗为模板分子,采用沉淀聚合法合成了克伦特罗的分子印迹聚合物,并以其为离子载体,制得分子印迹聚合物膜克伦特罗离子选择性电极。在最优实验条件下,电极对克伦特罗阳离子的检出限可达7.0×10-8mol/L,线性范围为1.0×10-7～1.0×10-4mol/L,能斯特斜率为55.7 mV/decade。此电极具有优越的选择性、快速的响应时间以及良好的稳定性;已成功应用于实际猪尿样品中克伦特罗的测定,加标回收率为98%～107%,检测时间小于3 min。     

基于石墨烯分子印迹电化学传感器测定芦丁

将石墨烯(GR)滴涂至裸Au电极表面,并以邻氨基酚为功能单体,芦丁为模板分子,制备了芦丁分子印迹膜电化学传感器,利用循环伏安法(CV)和差分脉冲伏安法(DPV)对制得的传感器进行了电化学性能研究,并且对制备条件和测定条件进行了优化。结果表明,与裸Au电极相比,该GR修饰的Au电极在[Fe(CN)_6]~(3-/4-)溶液中峰电流明显增大,显著提高了芦丁分子印迹传感器的灵敏度。在最优实验条件下,基于GR分子印迹电化学传感器在4.40×10~(-6)~2.80×10~(-4) mol/L范围内呈良好的线性关系,检测限为1.46×10~(-6) mol/L。用该传感器测定了黑茶中芦丁的含量,获得较好结果。     

石墨烯修饰电极分子印迹电化学传感器的研制及其对多巴胺的测定

以石墨烯为电极增敏材料,多巴胺印迹聚合物为特异性识别材料,采用滴涂法组装石墨烯修饰电极的分子印迹电化学传感器。考察了pH值、石墨烯浓度、印迹聚合物浓度对传感器的影响,优化的实验条件为:pH 7.0,石墨烯浓度为0.5g/L,印迹聚合物浓度为20g/L。实验表明,该印迹传感器对多巴胺的响应电流远大于非印迹电极,同时该印迹传感器对多巴胺具有较好的选择性,检测范围为2.0×10-7～1.0×10-4mol/L,检出限(S/N=3)为6.8×10-8mol/L。该传感器用于盐酸多巴胺注射液的测定,其回收率为98%～105%。     

基于还原氧化石墨烯-钯复合材料的双酚A分子印迹电化学传感器的研究

采用分子印迹技术,以还原氧化石墨烯-钯复合材料(rGO@Pd)修饰电极为工作电极,双酚A为模板分子,吡咯为聚合单体,成功制备出双酚A分子印迹电化学传感器。采用循环伏安法(CV)、差分脉冲伏安法(DPV)和电化学交流阻抗法(EIS)等,考察了该传感器的电化学性能。利用扫描电子显微镜(SEM)、傅立叶红外光谱(FT-IR)等技术对传感器表面进行结构分析。在最佳实验条件下,该电极的峰电流与双酚A在1.0~10.0 nmol/L浓度范围内呈良好线性关系,相关系数(r)为0.997 7,检出限(S/N=3)为0.1 nmol/L。该电极表现出良好的灵敏度、选择性、重现性和稳定性,已成功应用于自来水中双酚A含量的测定,加标回收率为92.1%~108.0%。     

基于纳米氧化锌-还原氧化石墨烯的分子印迹光电化学传感器测定土霉素

利用水热法合成了纳米氧化锌-还原氧化石墨烯（rGO）复合材料,采用傅里叶变换红外光谱、X射线衍射和X射线光电子能谱确定此复合材料的价态结构。以ZnO-rGO作为光电化学传感器的光电转换材料,以土霉素（OTC）为模板分子,通过电聚合OTC和吡咯（Py）的方法构建分子印迹光电化学传感器。将聚吡咯（PPy）膜中的OTC洗脱后,在PPy膜中留下OTC的特异性“印迹孔穴”,从而可对OTC选择性识别。在优化的条件下,此传感器的光电流变化值与OTC浓度（0.1～200 nmol/L）的对数值具有良好的线性关系,检出限为0.05 nmol/L(S/N=3)。采用此传感器对市售牛奶和蜂蜜中的OTC进行测定,回收率为95%～107%。     

基于石墨烯掺杂金纳米粒子的速灭威分子印迹电化学传感器

以速灭威(MTMC)为模板分子,甲基丙烯酸(MAA)为功能单体,马来松香丙烯酸乙二醇酯(EGMRA)为交联剂,在石墨烯掺杂金纳米粒子修饰玻碳电极表面合成分子印迹膜,研制了测定MTMC的分子印迹电化学传感器。采用扫描电镜(SEM)对传感膜的形貌进行了表征,通过循环伏安法(CV)、电化学阻抗谱法(EIS)和差示脉冲伏安法(DPV)对传感器的性能进行了研究。DPV测试表明,MTMC的浓度在1.0×10-7~1.0×10-4mol/L范围内呈现良好的线性关系(线性相关系数为R=0.9936),检出限2.9×10-8mol/L(S/N=3)。传感器应用于蔬菜样品的加标回收检测,回收率在93.4%~106.4%之间。     

基于石墨烯修饰的铜离子印迹电化学传感器研制与应用

以铜离子为模板离子,多巴胺为功能单体,采用电聚合法在石墨烯修饰碳电极表面成功制备对铜离子有高选择性和高灵敏性的印迹电化学传感器。采用差分脉冲伏安法和循环伏安法对该印迹传感器的电化学行为进行详细研究。优化检测条件,该印迹电化学传感器的响应电流与铜离子浓度的负对数在5×10_-6~5×10_-11 mol/L的浓度范围内呈良好的线性关系,最低检测限为1.0 × 10_-11mol/L。该印迹电化学传感器成功用于实际水样中的微量铜离子分析。     

A Review of Glucose Biosensors Based on Graphene/Metal Oxide Nanomaterials

In recent years, considerable attention has been paid to developing economical yet rapid glucose sensors using graphene and its composites. Recently, the excellent properties of graphene and metal oxide nanoparticles have been combined to provide a new approach for highly sensitive glucose sensors. This review focuses on the development of graphene functionalized with different nanostructured metal oxides (such as copper oxide, zinc oxide, nickel oxide, titanium dioxide, iron oxide, cobalt oxide, and manganese dioxide) for use as glucose biosensors. Additionally, a brief introduction of the electrochemical principles of glucose biosensors (including amperometric, potentiometric, and conductometric) is presented. Finally, the current status and future prospects are outlined for graphene/metal oxide nanomaterials in glucose sensing.     

氧化石墨掺杂的电化学活性自支撑聚苯胺膜

以氧化石墨（GO）为掺杂剂和模板,采用化学原位聚合法并通过调节苯胺单体和氧化石墨的质量比,合成了层状结构的聚苯胺/氧化石墨(PANI/GO)层状结构的自支撑膜。SEM和XRD研究表明,当苯胺单体与GO的质量比为67:1时,PANI/GO复合材料具有层间距~1.36 nm的层状结构,证实 GO的模板功能。XPS和FTIR研究表明PANI/GO复合材料中的典型的聚苯胺的掺杂态,进一步证实GO的掺杂功能。此外,电化学和热失重测量表明PANI/GO层状结构的自支撑膜呈现良好的热稳定性和高电化学活性.     

Graphene Oxide/Carbon Nanocoil Composite for High-performance Humidity Sensor

Designing a humidity sensor with high performance to quick and accurate detect relative humidity (RH) is important in various applications. Consideration must be given to both the high response and the quick reversibility. Here, based on Quartz Crystal Microbalance (QCM) sensing platform, we utilized commercial graphene oxide as a sensing material, and added commercial carbon nanocoil to block the stacking of graphene oxide layers. The fabricated novel sensor possessed super high response (4618 Hz/97 % RH) and quick reversibility (2 s). This work not only expands the application of commercial carbon materials, but also achieves the development of high-performance humidity sensor with commercial potential.     

Total Determination of Estrogenic Phenolic Compounds in River Water Using a Sensor Based on Reduced Graphene Oxide and Molecularly Imprinted Polymer

The contamination of water and wastewater by emerging pollutants, due to the anthropogenic activities, are an environmental problem that generates several negative impacts. In this range of species, steroids have gaining notoriety because their action of endocrine‐disruption. In this work, they are called estrogenic phenolic compounds (EPCs): estrone (E₁), estradiol (E₂), ethinyl estradiol (EE₂) and estriol (E₃), for determination using an electrochemical sensor based on reduced graphene oxide (rGO) and molecularly imprinted polymer (MIP). The analytical method developed, allied with the experimental and operational optimizations, proved to be effective for the total quantification of the EPCs in river water. The method shows sensitivity of 1.12 μA/μmol L⁻¹, detection limit of 26.8 nmol L⁻¹ and linear range of 0.16–15 μmol L⁻¹. The similar electrochemical behavior of the four compounds studied (E₁, E₂, EE₂ and E₃) and the efficiency of the modified composite (rGO, MIP) in the fabrication of the sensor resulted in high electrical conductivity and selective adsorptivity, respectively.     

An Electrochemical Sensing Platform Based on Graphene Oxide and Molecularly Imprinted Polymer Modified Electrode for Selective Detection of Amoxicillin

An electrochemical sensing platform based on composite material, consisting of molecularly imprinted polymer coated on graphene oxide (MIP-GO), was developed for selective and sensitive analysis of amoxicillin (AMOX). The MIP-GO composite, which was fabricated by sol-gel polymerization after removal of template molecule, was deposited as a thin film on glassy carbon electrode, and then was electrochemically characterized by cyclic voltammetry and differential pulse voltammetry. The linear response for the determination of AMOX was obtained in the concentration range from 5.0×10⁻¹⁰ to 9.1×10⁻⁷ M under the most proper conditions and the detection limit was found to be 2.94×10⁻¹⁰ M.     

石墨烯薄膜的光化学还原制备与表征

采用光化学还原方法制备了图案化的石墨烯薄膜.研究了光还原氧化石墨烯薄膜(PRGO)的热稳定性和发光性质.热重分析(TGA)结果表明,光化学还原主要引起氧化石墨烯(GO)氧化基团的减少,而对GO内水含量影响较小;发光(PL)测试结果表明,不同激发条件下,PRGO的发光与GO相比表现出了不同的变化规律:在波长514 nm的光激发下,PRGO的发光强度比GO明显降低,同时伴随着发光峰峰位红移;而在波长830 nm的光激发下,PRGO的发光强度比GO略有增强,并且发光峰峰位无明显变化,此结果表明不同尺寸的碳团簇局域态(sp2C团簇)的光还原反应活性不同,这与GO特殊的能带结构密切相关.     

Graphene Doped Molecularly Imprinted Electrochemical Sensor for Uric Acid

A highly sensitive uric acid molecularly imprinted electrochemical sensor was prepared by using graphene doped chitosan as the functional matrix and uric acid as the template molecule; a electrodeposition technique was used to form a controllable graphene–chitosan–uric acid composited film on glassy carbon electrode whose uric acid was removed via electrochemical induce elution. Under the optimized preparation and detection conditions, the detection sensitivity of uric acid at graphene doped molecularly imprinted sensor was improved significantly compared with the undoped molecularly imprinted sensor. The mechanisms of sensitivity enhancement were studied by a.c. electrochemical impedance, adsorption model, and chronocoulometry. The observations suggest the effect of sensitivity enhancement resulted from magnified surface area and good electronic conduction of graphene. Additionally, the developed sensor exhibited specific recognition to uric acid against the competitors which consisted of structure liked substances and coexisting interference in blood serum.     

Development of a Potentiometric Chemical Sensor for the Rapid Detection of Carbofuran Based on Air Stable Lipid Films with Incorporated Calix[4]arene Phosphoryl Receptor Using Graphene Electrodes

The present article describes a miniaturized potentiometric carbofuran chemical sensor on graphene nanosheets with incorporated lipid films. The graphene electrode was used for the development of a very selective and sensitive chemical sensor for the detection of carbofuran by immobilizing an artificial selective receptor on stabilized lipid films. The artificial receptor was synthesized by transformation of the hydroxyl groups of resorcin[4]arene receptor into phosphoryl groups. This chemical sensor responded for the wide range of carbofuran concentrations with fast response time of ca. 20 s. The presented potentiometric carbofuran chemical sensor is easy to construct and exhibits good reproducibility, reusability, selectivity, rapid response times, long shelf life and high sensitivity of ca. 59 mV/decade over the carbofuran logarithmic concentration range from 10^?6 to 10^?3 M.