A Performance Comparison Between Organic Electrochemical Transistor and Electrode Configurations for Enzymatic Sensing

Abdulelah Saleh, Shofarul Wustoni, Luca Salvigni, Anil Koklu, Victor Druet, Jokubas Surgailis, Prem D. Nayak, Sahika Inal
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Abstract

Organic electrochemical transistors (OECTs) excel at biosensing due to their high amplification factor, which allows for detecting low analyte concentrations and picking up weak physiological signals. One prominent use of OECT is in enzymatic metabolite sensing, with the OECT claimed to have a superior low limit of detection and enhanced sensitivity compared to conventional two or three electrode-based setups. However, there has yet to be a direct comparative study on the performance metrics of these sensor configurations under unified conditions. Here, the glucose sensing performance of an enzyme-immobilized electrode is systematically examined in two types of devices that have the same geometrical relations: the first one is a traditional 2- or 3-electrode configuration where the sensing electrode is the working electrode, and in the second one, the enzymatic electrode serves as the gate electrode of an OECT. While benchmarking the performance of OECT technology for enzyme-based metabolite sensing, this study provides insights into the operation mechanism of OECT-based enzymatic sensors. These results can help to design more efficient OECT-based circuits to transduce biological events that involve redox reactions.

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用于酶传感的有机电化学晶体管和电极配置的性能比较
有机电化学晶体管(OECT)因其高放大系数而在生物传感方面表现出色,可检测低浓度的分析物并捕捉微弱的生理信号。OECT 的一个突出用途是酶代谢物传感,据称与传统的基于两个或三个电极的装置相比,OECT 具有更优越的低检测限和更高的灵敏度。然而,目前还没有在统一条件下对这些传感器配置的性能指标进行直接比较研究。在这里,我们系统地研究了酶固定电极在两种具有相同几何关系的装置中的葡萄糖传感性能:第一种是传统的双电极或三电极配置,其中传感电极是工作电极;第二种是酶电极作为 OECT 的栅电极。在为基于酶的代谢物传感设定 OECT 技术性能基准的同时,本研究还深入探讨了基于 OECT 的酶传感器的运行机制。这些结果有助于设计更高效的基于 OECT 的电路,以传递涉及氧化还原反应的生物事件。
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