ELECTROCHEMICAL BIOSENSORS FOR CONT­ROL OF LEAD CONTENT IN THE ENVIRONMENT. A REVIEW

L. Zinko, Yelyzaveta Pletenets
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Abstract

The review presents different types of biosensors and their principles of operation that are currently used to detect heavy metals and lead. Biosensors are considered highly sensitive, specific, accurate, inexpensive and effective tools for the preliminary detection of one or more metals in sources of mixed pollution, especially in wastewater. The use of functional nanomaterials based on metal-organic frameworks and layered hydroxides allowed to miniaturize the design of biosensors and significantly improve their applicability for on-site analysis of target samples, which reduces the probability of any changes in the samples during transport to the laboratory. Also, these materials have long-term stability, improve the signal and response speed of electrochemical biosensors, and also increase their sensitivity and selectivity. An overview of the methods of manufacturing the active component of multilayer electrochemical sensors was conducted. The main methods of obtaining stable and sensitive to lead ions electrochemical systems are noted.Sensors and biosensors are powerful tools for accurate qualitative and quantitative analysis of a specific analyte and integration of biotechnology, microelectronics, and nanotechnology to fabricate miniaturized devices without loss of sensitivity, specificity, and cont­rol accuracy. The characteristic properties of biomolecule carriers significantly affect the sensitivity and selectivity of the device. The impact of carriers based on metal-organic frameworks and layered hydroxides on increasing the efficiency of modern lead biosensors due to the implementation of the enzyme inhibition mechanism was considered, and the me­thods of manufacturing the active component of multilayer electrochemical sensors were also reviewed. The perspective of using the coprecipitation method and the ion exchange method to obtain stable and sensitive lead ion electrochemical systems was noted. Thus, electrochemical biosensors can be considered as one of the most widely developed biosensors for the detection of lead ions, in which the presence of direct electron transfer from the recognition center to the electrode reduces the probability of unnecessary interference, which significantly increases their sensitivity and selectivity and enables the development of devices for in-mode monitoring real-time.
控制环境中铅含量的电化学生物传感器。回顾
本文介绍了目前用于检测重金属和铅的不同类型的生物传感器及其工作原理。生物传感器被认为是高度敏感、特异、准确、廉价和有效的工具,用于初步检测混合污染源中的一种或多种金属,特别是在废水中。基于金属有机框架和层状氢氧化物的功能纳米材料的使用使生物传感器的设计小型化,并显著提高了其对目标样品现场分析的适用性,从而降低了样品在运输到实验室过程中发生任何变化的可能性。此外,这些材料具有长期稳定性,提高了电化学生物传感器的信号和响应速度,也提高了它们的灵敏度和选择性。综述了多层电化学传感器有源元件的制备方法。介绍了获得稳定、灵敏的铅离子电化学体系的主要方法。传感器和生物传感器是对特定分析物进行精确定性和定量分析的强大工具,是生物技术、微电子和纳米技术的集成,在不损失灵敏度、特异性和控制精度的情况下制造小型化设备。生物分子载体的特性显著影响器件的灵敏度和选择性。讨论了基于金属-有机框架和层状氢氧化物的载体由于酶抑制机制的实现对现代铅生物传感器效率提高的影响,并对多层电化学传感器活性组分的制备方法进行了综述。展望了利用共沉淀法和离子交换法获得稳定、灵敏的铅离子电化学体系的前景。因此,电化学生物传感器可以被认为是最广泛发展的用于铅离子检测的生物传感器之一,其中从识别中心到电极的直接电子转移的存在减少了不必要干扰的可能性,这大大提高了它们的灵敏度和选择性,并使开发出实时监测设备成为可能。
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