Ultrahigh sensitivity slot-waveguide biosensor on a highly integrated chip for simultaneous diagnosis of multiple diseases

D. Hill
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Abstract

SABIO is a multidisciplinary project involving the emerging fields of micro-nano technology, photonics, fluidics and bio-chemistry, targeting a contribution to the development of intelligent diagnostic equipment through the demonstration of a compact polymer based and silicon-based CMOS-compatible micro-nano system. It integrates optical biosensors for label-free biomolecular recognition based on a novel photonic structure named slot-waveguide with immobilised biomolecular receptors on its surface. The slot-waveguides provide high optical intensity in a subwavelength-size low refractive index region (slot-region) sandwiched between two high refractive index strips (rails) [Almeida, V., et al., 2004] leading to an enhanced interaction between the optical probe and biomolecular complexes (antibody-antigen). As such a biosensor is predicted to exhibit a surface concentration detection-limit lower than 1 pg/mm2, state-of-the-art in label-free integrated optical biosensors, as well as the possibility of multiplexed assay, which, together with reduced reaction volumes, leads to the ability to perform rapid multi-analyte sensing and comprehensive tests. This offers the further advantageous possibility of assaying several parameters simultaneously and consequently, statistical analysis of these results can potentially increase the reliability and reduce the measurement uncertainty of a diagnostic over single-parameter assays. In addition, the SABIO micro-nano system device applied to its novel protein-based diagnostic technology has the potential to be fast and easy to use, making routine screening or monitoring of diseases more cost-effective.
基于高度集成芯片的超高灵敏度槽波导生物传感器,可同时诊断多种疾病
SABIO是一个多学科项目,涉及微纳米技术、光子学、流体学和生物化学等新兴领域,旨在通过展示紧凑型聚合物基和硅基cmos兼容微纳米系统,为智能诊断设备的发展做出贡献。它集成了用于无标记生物分子识别的光学生物传感器,该传感器基于一种新型的光子结构,称为槽波导,其表面有固定的生物分子受体。狭缝波导在夹在两个高折射率条带(轨道)之间的亚波长大小的低折射率区域(狭缝区域)中提供高光强[Almeida, V.等,2004],从而增强了光学探针与生物分子复合物(抗体-抗原)之间的相互作用。由于预计这种生物传感器的表面浓度检测极限低于1 pg/mm2,最先进的无标签集成光学生物传感器,以及多路分析的可能性,加上减少的反应体积,导致能够执行快速的多分析物传感和综合测试。这为同时分析多个参数提供了进一步的有利可能性,因此,对这些结果进行统计分析可以潜在地增加可靠性,并减少单参数分析的诊断测量不确定性。此外,将SABIO微纳米系统设备应用于其新型基于蛋白质的诊断技术,具有快速和易于使用的潜力,使常规筛查或疾病监测更具成本效益。
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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