Mohanaraj Sanuja, Wonnenberg Pauline, Cohen Brianna, Zhao He, Hartings Matthew R, Zou Shouzhong, Fox Douglas M, Zestos Alexander G
Department of Chemistry, American University.
Department of Chemistry, American University; Center for Behavioral Neuroscience, American University;
J Vis Exp. 2019 May 13(147). doi: 10.3791/59552.
For over 30 years, carbon-fiber microelectrodes (CFMEs) have been the standard for neurotransmitter detection. Generally, carbon fibers are aspirated into glass capillaries, pulled to a fine taper, and then sealed using an epoxy to create electrode materials that are used for fast scan cyclic voltammetry testing. The use of bare CFMEs has several limitations, though. First and foremost, the carbon fiber contains mostly basal plane carbon, which has a relatively low surface area and yields lower sensitivities than other nanomaterials. Furthermore, the graphitic carbon is limited by its temporal resolution, and its relatively low conductivity. Lastly, neurochemicals and macromolecules have been known to foul at the surface of carbon electrodes where they form non-conductive polymers that block further neurotransmitter adsorption. For this study, we modify CFMEs with gold nanoparticles to enhance neurochemical testing with fast scan cyclic voltammetry. Au was electrodeposited or dipcoated from a colloidal solution onto the surface of CFMEs. Since gold is a stable and relatively inert metal, it is an ideal electrode material for analytical measurements of neurochemicals. Gold nanoparticle modified (AuNP-CFMEs) had a stability to dopamine response for over 4 h. Moreover, AuNP-CFMEs exhibit an increased sensitivity (higher peak oxidative current of the cyclic voltammograms) and faster electron transfer kinetics (lower ΔEP or peak separation) than bare unmodified CFMEs. The development of AuNP-CFMEs provides the creation of novel electrochemical sensors for detecting fast changes in dopamine concentration and other neurochemicals at lower limits of detection. This work has vast applications for the enhancement of neurochemical measurements. The generation of gold nanoparticle modified CFMEs will be vitally important for the development of novel electrode sensors to detect neurotransmitters in vivo in rodent and other models to study neurochemical effects of drug abuse, depression, stroke, ischemia, and other behavioral and disease states.
30多年来,碳纤维微电极(CFMEs)一直是神经递质检测的标准。一般来说,将碳纤维吸入玻璃毛细管,拉成细锥形,然后用环氧树脂密封,制成用于快速扫描循环伏安法测试的电极材料。然而,使用裸CFMEs存在一些局限性。首先,碳纤维主要包含基面碳,其表面积相对较低,与其他纳米材料相比灵敏度较低。此外,石墨碳受其时间分辨率和相对较低的电导率限制。最后,已知神经化学物质和大分子会在碳电极表面形成污垢,并在那里形成非导电聚合物,从而阻止进一步的神经递质吸附。在本研究中,我们用金纳米颗粒修饰CFMEs,以增强快速扫描循环伏安法的神经化学测试。金通过电沉积或从胶体溶液浸涂到CFMEs表面。由于金是一种稳定且相对惰性的金属,它是用于神经化学物质分析测量的理想电极材料。金纳米颗粒修饰的(AuNP-CFMEs)对多巴胺反应的稳定性超过4小时。此外,与未修饰的裸CFMEs相比,AuNP-CFMEs表现出更高的灵敏度(循环伏安图的氧化电流峰值更高)和更快的电子转移动力学(更低的ΔEP或峰间距)。AuNP-CFMEs的开发为检测多巴胺浓度和其他神经化学物质在更低检测限下的快速变化提供了新型电化学传感器。这项工作在增强神经化学测量方面有广泛应用。金纳米颗粒修饰的CFMEs的产生对于开发新型电极传感器以在啮齿动物和其他模型中体内检测神经递质至关重要,从而研究药物滥用、抑郁症、中风、缺血以及其他行为和疾病状态的神经化学效应。