Development of an electrochemical biosensor with TiN nano-electrode arrays for IL-6 detection

IF 6.5 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Sensors and Actuators Reports Pub Date : 2024-06-01 DOI:10.1016/j.snr.2024.100204
Shu-Tsai Cheng , Ching-Fen Shen , Jeng-Huei Shiau , Kuan-Ru Chou , Wei-Yu Lin , Chun-Lung Lien , Chao-Min Cheng
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Abstract

In this study, we developed a novel electrochemical biosensor for detecting IL-6 that uses a nano-electrode array (NEA) fabricated via standard CMOS processing. Miniaturizing the electrodes to the nanoscale and arranging them in an array to form an NEA facilitated the creation of a higher electric field magnitude, compared to that available via the use of microelectrodes, that could be used to improve biosensor sensitivity. Additionally, the array configuration of the NEA aided in providing sufficient reaction sites. Each nano-electrode in the NEA was cylindrically shaped, with a radius of 0.1 µm, and a top layer formed by TiN physical vapor deposition. Each NEA biosensor was divided into four independent banks, with each bank including a set of WE, CE and RE. These banks were capable of independently inputting and outputting electrical signals. This design allowed the NEA biosensor to undergo selective modification by CV input. In this study, we discuss and address material and contamination issues associated with CMOS-produced NEAs and their uses as biosensors. To ameliorate these issues, we stored materials and products in a nitrogen-controlled cabinet and conducted pretreatment cleaning on the electrodes. Both steps had a noticeable impact on the cleanliness of the electrode surfaces. These optimized conditions resulted in a remarkable 96.6 % reduction in Rct. The NEA surface was functionalized by electrochemically grafting diazonium salts subsequently immobilized with anti-IL-6 antibodies via EDC/NHS chemistry. The resulting NEA biosensor demonstrated sufficient sensitivity to rapidly distinguish inflammatory conditions and disease severity. This showcases the potential for using NEA devices mass-produced via standard CMOS processing as electrodes for biosensors.

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利用 TiN 纳米电极阵列开发用于检测 IL-6 的电化学生物传感器
在这项研究中,我们开发了一种用于检测 IL-6 的新型电化学生物传感器,该传感器使用通过标准 CMOS 工艺制作的纳米电极阵列 (NEA)。与使用微电极相比,将电极微型化到纳米级并将其排列成阵列形成 NEA 有助于产生更高的电场幅度,从而提高生物传感器的灵敏度。此外,NEA 的阵列配置有助于提供足够的反应位点。NEA 中的每个纳米电极都呈圆柱形,半径为 0.1 微米,顶层由 TiN 物理气相沉积形成。每个 NEA 生物传感器分为四个独立的组,每个组包括一组 WE、CE 和 RE。这些组能够独立输入和输出电信号。这种设计允许 NEA 生物传感器通过 CV 输入进行选择性修改。在本研究中,我们讨论并解决了与 CMOS 生产的 NEA 及其生物传感器用途相关的材料和污染问题。为了改善这些问题,我们将材料和产品储存在氮气控制柜中,并对电极进行了预处理清洁。这两个步骤都对电极表面的清洁度产生了明显的影响。这些优化条件使 Rct 显著降低了 96.6%。通过电化学接枝重氮盐使 NEA 表面功能化,然后通过 EDC/NHS 化学固定抗 IL-6 抗体。由此产生的 NEA 生物传感器具有足够的灵敏度,可快速区分炎症状况和疾病严重程度。这展示了将通过标准 CMOS 工艺批量生产的 NEA 器件用作生物传感器电极的潜力。
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来源期刊
CiteScore
9.60
自引率
0.00%
发文量
60
审稿时长
49 days
期刊介绍: Sensors and Actuators Reports is a peer-reviewed open access journal launched out from the Sensors and Actuators journal family. Sensors and Actuators Reports is dedicated to publishing new and original works in the field of all type of sensors and actuators, including bio-, chemical-, physical-, and nano- sensors and actuators, which demonstrates significant progress beyond the current state of the art. The journal regularly publishes original research papers, reviews, and short communications. For research papers and short communications, the journal aims to publish the new and original work supported by experimental results and as such purely theoretical works are not accepted.
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