Simulation of Prostate Specific Antigen (PSA) ISFET Sensor with Different Nanostructures

ELEKTRIKA- Journal of Electrical Engineering Pub Date : 2023-04-28 DOI:10.11113/elektrika.v22n1.407

Lee Shung Mun, Suhana Mohamed Sultan, Nur Afiqah Ab Razak

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Abstract

It is crucial to have early detection of prostate cancer as it is the third most common cancer in men and Prostate Specific Antigen (PSA) is a protein-based biomarker commonly used to achieve the purpose. Besides, ISFET integrated with nanostructures such as nanowire and nanosphere has been the focus of research for disease diagnosis. Simulations are carried out in Biosensor Lab to investigate the performance of ISFET with planar, nanowire and nanosphere structures in detecting PSA. Using nanostructured ISFET in disease diagnosis is demonstrated by comparing the performance with the surface-to-volume (S/V) ratio. The nanosphere biosensor with the highest S/V ratio showed the lowest settling time when there was a low analyte concentration. Its settling time is 788 times lower than planar and almost 3 times lower than nanowire ISFET. In addition, the time needed for a planar biosensor to capture M of PSA is 5 times slower than a nanowire biosensor and nanosphere biosensor. In signal-to-noise ratio (SNR), nanosphere ISFET exhibits the highest value compared to other structures. These results indicate that a higher S/V ratio contributed to better performance in detecting PSA.

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不同纳米结构前列腺特异抗原(PSA) ISFET传感器的模拟

前列腺癌是男性第三大常见癌症，早期发现前列腺癌至关重要，而前列腺特异性抗原(PSA)是一种基于蛋白质的生物标志物，通常用于实现这一目标。此外，集成了纳米线、纳米球等纳米结构的ISFET已成为疾病诊断研究的热点。在生物传感器实验室进行了模拟，研究了平面结构、纳米线结构和纳米球结构的ISFET检测PSA的性能。通过与表面体积比(S/V)的比较，证明了纳米结构ISFET在疾病诊断中的应用。当分析物浓度较低时，S/V比最高的纳米球生物传感器的沉降时间最短。其沉降时间比平面ISFET低788倍，比纳米线ISFET低近3倍。此外，平面生物传感器捕获M的PSA所需的时间比纳米线生物传感器和纳米球生物传感器慢5倍。在信噪比(SNR)方面，纳米球ISFET与其他结构相比表现出最高的值。这些结果表明，较高的信噪比有助于提高检测PSA的性能。

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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ELEKTRIKA- Journal of Electrical Engineering

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