EaStCHEM, School of Chemistry, The University of Edinburgh, Joseph Black Building, The King's Buildings, West Mains Road, Edinburgh EH9 3FJ, UK.
Department of Biomedical Engineering, University of Strathclyde, Glasgow G4 0NS, UK.
Sensors (Basel). 2018 Jun 9;18(6):1891. doi: 10.3390/s18061891.
For analytical applications involving label-free biosensors and multiple measurements, i.e., across an electrode array, it is essential to develop complete sensor systems capable of functionalization and of producing highly consistent responses. To achieve this, a multi-microelectrode device bearing twenty-four equivalent 50 µm diameter Pt disc microelectrodes was designed in an integrated 3-electrode system configuration and then fabricated. Cyclic voltammetry and electrochemical impedance spectroscopy were used for initial electrochemical characterization of the individual working electrodes. These confirmed the expected consistency of performance with a high degree of measurement reproducibility for each microelectrode across the array. With the aim of assessing the potential for production of an enhanced multi-electrode sensor for biomedical use, the working electrodes were then functionalized with 6-mercapto-1-hexanol (MCH). This is a well-known and commonly employed surface modification process, which involves the same principles of thiol attachment chemistry and self-assembled monolayer (SAM) formation commonly employed in the functionalization of electrodes and the formation of biosensors. Following this SAM formation, the reproducibility of the observed electrochemical signal between electrodes was seen to decrease markedly, compromising the ability to achieve consistent analytical measurements from the sensor array following this relatively simple and well-established surface modification. To successfully and consistently functionalize the sensors, it was necessary to dilute the constituent molecules by a factor of ten thousand to support adequate SAM formation on microelectrodes. The use of this multi-electrode device therefore demonstrates in a high throughput manner irreproducibility in the SAM formation process at the higher concentration, even though these electrodes are apparently functionalized simultaneously in the same film formation environment, confirming that the often seen significant electrode-to-electrode variation in label-free SAM biosensing films formed under such conditions is not likely to be due to variation in film deposition conditions, but rather kinetically controlled variation in the SAM layer formation process at these microelectrodes.
对于涉及无标记生物传感器和多次测量的分析应用,即在电极阵列上,开发能够进行功能化并产生高度一致响应的完整传感器系统至关重要。为了实现这一目标,设计了一个具有 24 个等效 50μm 直径 Pt 圆盘微电极的多微电极器件,采用集成 3 电极系统配置,并进行了制造。循环伏安法和电化学阻抗谱用于对单个工作电极进行初始电化学表征。这些证实了预期的性能一致性,每个微电极在阵列上具有高度的测量可重复性。为了评估生产用于生物医学用途的增强型多电极传感器的潜力,然后将工作电极用 6-巯基-1-己醇 (MCH) 功能化。这是一种众所周知且常用的表面修饰过程,涉及到与电极功能化和生物传感器形成相同的硫醇附着化学和自组装单层 (SAM) 形成原理。在这种 SAM 形成之后,观察到电极之间电化学信号的重现性明显下降,这使得在进行相对简单且成熟的表面修饰后,无法从传感器阵列获得一致的分析测量。为了成功且一致地功能化传感器,有必要将组成分子稀释一万倍,以支持微电极上足够的 SAM 形成。因此,即使这些电极在相同的薄膜形成环境中同时功能化,即使在较高浓度下,多电极器件的使用也以高通量的方式证明了 SAM 形成过程的不可重复性,这证实了在这种条件下形成的无标记 SAM 生物传感膜中经常看到的电极之间的显著电极变化,不是由于膜沉积条件的变化,而是由于这些微电极上 SAM 层形成过程的动力学控制变化。
