Shear horizontal SAW biosensor on langasite

Proceedings of IEEE Sensors 2003 (IEEE Cat. No.03CH37498) Pub Date : 2003-10-22 DOI:10.1109/ICSENS.2003.1279020

E. Berkenpas, M. Pereira da Cunha, S. Bitla, P. Millard

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引用次数: 4

Abstract

Pathogenic microbial agents can be introduced into food, water supplies, or atmosphere as a result of accidents, pollution, or terrorist activity. Sensitive and selective sensors are urgently needed to detect minute quantities of pathogens rapidly and accurately. SH SAW devices provide opportunities for the design of microbial sensing platforms that function in liquid media, where most other SAW modes fail. A SH SAW delay line device was designed and fabricated on a novel LGS SH orientation. The biosensor measurements were carried out using a network analyzer S-parameter and impedance characterization. A specialized flow through system was developed to perform liquid phase biological testing on the SH SAW device. Sensitivity to biomolecule binding in physiological solutions was tested by sequential binding of specific protein species to the modified sensing surface. A self-assembling monolayer of cysteamine was formed on the gold sensing region of the delay line and the resulting terminal amine moieties reacted with alkyl NHS-biotin to produce a biotin-rich sensor surface. The biotinylated sensor was then exposed sequentially to biotin-binding Neutravidin, biotin-modified rabbit IgG, and goat anti-rabbit IgG antibody. As each protein was bound sequentially to the sensing surface, marked changes in the delay line phase were recorded. The reported results demonstrating the capability of these devices for sensitive biochemical recognition in acequous solutions reveals an important development in SAW based biosensor technology.

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langasite上剪切水平SAW生物传感器

由于事故、污染或恐怖活动，病原微生物可以被引入食物、水供应或大气中。迫切需要灵敏和选择性的传感器来快速准确地检测微量病原体。SH SAW装置为液体介质微生物传感平台的设计提供了机会，而大多数其他SAW模式都无法在液体介质中工作。设计并制作了一种基于新型LGS SH取向的shsaw延迟线器件。生物传感器测量使用网络分析仪进行s参数和阻抗表征。开发了一种专门的流动系统，用于在SH SAW装置上进行液相生物测试。对生理溶液中生物分子结合的敏感性是通过将特定蛋白质物种顺序结合到修饰的传感表面来测试的。在延迟线的金传感区形成自组装单层半胱胺，末端胺部分与烷基nhs -生物素反应生成富生物素传感器表面。然后将生物素化的传感器依次暴露于生物素结合的neutridin、生物素修饰的兔IgG和山羊抗兔IgG抗体中。当每个蛋白依次结合到传感表面时，记录延迟线相位的明显变化。报道的结果表明，这些设备能够在水溶液中进行敏感的生化识别，这揭示了基于SAW的生物传感器技术的重要发展。

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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Proceedings of IEEE Sensors 2003 (IEEE Cat. No.03CH37498)

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