Modelling impedance for 3D impedimetric biosensor

2015 9th International Conference on Sensing Technology (ICST) Pub Date : 2015-12-01 DOI:10.1109/ICSENST.2015.7438360

J. Yeh, K. Wang, Z. Salcic, Karthik Kannappan, A. Partridge

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引用次数: 1

Abstract

There is a growing need for new biosensing technologies that are more rapid and convenient to use for onsite sensing. Impedance-based electrochemical sensor is a promising candidate due to simplicity of its sensing mechanism. However, like other emerging biosensors, specificity, sensitivity, and reliability are major obstacles that limit their use in real-life applications. Electrode geometry and 3D shape design optimization have been popular research directions for improved sensor performance. The aim of this study is to develop a finite element modelling approach that allows calculation of electrode impedance for different electrode shapes under standard biological test medium. In addition, a method for comparing sensor sensitivity is also developed using bacterial target as case study. Impedance simulations were performed for different electrode shapes, namely flat, ridge, and trough. The effects of target binding on solution conductivity and diffusion were simulated. It was found trough shaped electrode showed the greatest change in diffusion impedance upon target recognition. However, different shapes gave maximum change in solution impedance depending on the position of bound target.

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三维阻抗生物传感器的阻抗建模

人们对新的生物传感技术的需求日益增长，这种技术可以更快速、更方便地用于现场传感。基于阻抗的电化学传感器由于其传感机制简单，是一种很有前途的候选传感器。然而，像其他新兴的生物传感器一样，特异性、灵敏度和可靠性是限制其在实际应用中的主要障碍。电极几何和三维形状设计优化是提高传感器性能的热门研究方向。本研究的目的是开发一种有限元建模方法，允许在标准生物测试介质下计算不同电极形状的电极阻抗。此外，还以细菌靶为例，提出了一种比较传感器灵敏度的方法。阻抗模拟进行了不同的电极形状，即平面，脊和槽。模拟了靶结合对溶液电导率和扩散的影响。发现槽形电极在识别目标时扩散阻抗变化最大。然而，不同形状的解阻抗随绑定目标的位置变化最大。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 9th International Conference on Sensing Technology (ICST)

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