Flake like Copper Oxide Nanostructures and their Application in Electrocatalytic Sensing of Growth-Promoting Agents

Nizamuddin Solangi, Sorath Solangi, G. Naz, G. Mastoi
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Abstract

A compact and intimate interfacial contact between the modified film and the conducting electrode is crucial for electrochemical biosensors. The direct drop-casting of nanomaterials onto the working electrode often fails to construct a compact interfacial arrangement, which results in sluggish electrode kinetics. Here, we describe a simple and cost-effective strategy to produce CuO nanostructure using a modified hydrothermal route. The in-situ growth allowed the formation of a highly ordered interconnected network of sharp flakes configured in the form of large spheres with excellent ITO surface coverage. The CuO nanostructures were highly electrochemically active toward the oxidation of β–adrenergic agonists, i.e., formoterol fumarate (FF). The analytical ability was studied by comparison of the electrochemical behavior of ITO based electrode with its glassy carbon electrode counterpart. The binder-less CuO-based ITO electrode successfully determined FF with a detection window of 0.01 µM to 0.46 µM with practical application for real broiler feed samples collected from the local poultry farms in Hyderabad, Pakistan.
片状氧化铜纳米结构及其在促生长剂电催化传感中的应用
改性膜与导电电极之间紧密的界面接触对电化学生物传感器至关重要。纳米材料直接滴铸到工作电极上往往不能形成紧密的界面排列,从而导致电极动力学缓慢。在这里,我们描述了一种简单而经济的策略,利用改进的水热途径生产CuO纳米结构。原位生长允许形成高度有序的相互连接的尖锐薄片网络,这些薄片以大球体的形式配置,具有出色的ITO表面覆盖。CuO纳米结构对β -肾上腺素能激动剂,即富马酸福莫特罗(FF)的氧化具有高度的电化学活性。通过比较ITO基电极与玻碳电极的电化学行为,研究了ITO基电极的分析能力。无粘结剂的cuo基ITO电极成功测定了FF,检测窗口为0.01µM ~ 0.46µM,并在巴基斯坦海得拉巴当地家禽养殖场的真实肉鸡饲料样品中得到了实际应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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