Evaluation of Transducer Elements Based on Different Material Configurations for Aptamer-Based Electrochemical Biosensors

Biosensors Pub Date : 2024-07-13 DOI:10.3390/bios14070341

Ivan Lopez Carrasco, Gianaurelio Cuniberti, Jörg Opitz, Natalia Beshchasna

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Abstract

The selection of an appropriate transducer is a key element in biosensor development. Currently, a wide variety of substrates and working electrode materials utilizing different fabrication techniques are used in the field of biosensors. In the frame of this study, the following three specific material configurations with gold-finish layers were investigated regarding their efficacy to be used as electrochemical (EC) biosensors: (I) a silicone-based sensor substrate with a layer configuration of 50 nm SiO/50 nm SiN/100 nm Au/30–50 nm WTi/140 nm SiO/bulk Si); (II) polyethylene naphthalate (PEN) with a gold inkjet-printed layer; and (III) polyethylene terephthalate (PET) with a screen-printed gold layer. Electrodes were characterized using electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV) to evaluate their performance as electrochemical transducers in an aptamer-based biosensor for the detection of cardiac troponin I using the redox molecule hexacyanoferrade/hexacyaniferrade (K3[Fe (CN)6]/K4[Fe (CN)6]. Baseline signals were obtained from clean electrodes after a specific cleaning procedure and after functionalization with the thiolate cardiac troponin I aptamers “Tro4” and “Tro6”. With the goal of improving the PEN-based and PET-based performance, sintered PEN-based samples and PET-based samples with a carbon or silver layer under the gold were studied. The effect of a high number of immobilized aptamers will be tested in further work using the PEN-based sample. In this study, the charge-transfer resistance (Rct), anodic peak height (Ipa), cathodic peak height (Ipc) and peak separation (∆E) were determined. The PEN-based electrodes demonstrated better biosensor properties such as lower initial Rct values, a greater change in Rct after the immobilization of the Tro4 aptamer on its surface, higher Ipc and Ipa values and lower ∆E, which correlated with a higher number of immobilized aptamers compared with the other two types of samples functionalized using the same procedure.

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评估基于不同材料配置的换能器元件，用于基于色聚体的电化学生物传感器

选择合适的传感器是开发生物传感器的关键因素。目前，生物传感器领域使用的基底和工作电极材料种类繁多，且采用了不同的制造技术。在本研究框架内，对以下三种具有金表面层的特定材料配置用作电化学（EC）生物传感器的功效进行了研究：(I) 硅基传感器基底，层配置为 50 nm SiO/50 nm SiN/100 nm Au/30-50 nm WTi/140 nm SiO/大块 Si）；(II) 具有喷墨打印金层的聚萘二甲酸乙二醇酯（PEN）；(III) 具有丝网打印金层的聚对苯二甲酸乙二醇酯（PET）。使用电化学阻抗谱（EIS）和循环伏安法（CV）对电极进行了表征，以评估它们在基于适配体的生物传感器中作为电化学传感器的性能，该传感器使用氧化还原分子六氰铁/六氰菲草（K3[Fe (CN)6]/K4[Fe (CN)6]）检测心肌肌钙蛋白 I。经过特定清洁程序和硫代心肌肌钙蛋白 I 配合物 "Tro4 "和 "Tro6 "功能化后，从清洁电极上获得了基线信号。为了提高基于 PEN 和 PET 的性能，研究了烧结的基于 PEN 的样品和在金下有碳或银层的基于 PET 的样品。在进一步的工作中，将使用基于 PEN 的样品测试大量固定化适配体的效果。本研究测定了电荷转移电阻（Rct）、阳极峰高（Ipa）、阴极峰高（Ipc）和峰间距（ΔE）。与使用相同程序功能化的其他两种样品相比，基于 PEN 的电极表现出更好的生物传感器特性，如初始 Rct 值较低，表面固定 Tro4 合体后 Rct 变化较大，Ipc 和 Ipa 值较高，ΔE 较低，这与固定的合体数量较多有关。

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Biosensors

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