Can classical surface plasmon resonance advance via the coupling to other analytical approaches?

David Geilfuss, R. Boukherroub, J. Dostálek, W. Knoll, J. Masson, A. Baeumner, S. Szunerits
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引用次数: 1

Abstract

For nearly 40 years, surface plasmon resonance (SPR) analysis has been used to better understand the binding interaction strength between surface immobilized bioreceptors and the analytes of interest. The advantage of surface plasmon resonance, over other affinity sensing approaches such as Western blots and ELISAs approaches, resides in its possibility to reveal binding kinetics in a label-free manner. The concept of surface plasmon resonance has in addition been widely employed for the development of biosensors capitalizing on its direct assay format, short response times, simple sample treatments along with multiplexed sensing possibilities. To this must be added the possibility to reach high sensitivity due to the capability of surface plasmon resonance to detect very small changes in refractive index at the sensing interfaces in particular for analytes of larger size such as cells (e.g., bacteria), proteins, peptides and oligonucleotides. Challenges inherent to all affinity approaches call for further research and include non-specific surface binding events, mass transportation restrictions, steric hindrance, and the risk of data misinterpretation in case of lack of selective analyte binding. This opinion article is devoted to outlining the different approaches proposed to address these challenges by e.g., coupling with fluorescence read out, electrochemical sensing, mass spectroscopy analysis and more recently to integrate lateral flow concepts into surface plasmon resonance. Other plasmonic methods such as localized surface plasmon resonance (LSPR), surface enhanced Raman spectroscopy (SERS) will not be considered in detail, as such techniques have nowadays their own standing.
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经典表面等离子体共振能否通过与其他分析方法的耦合而向前发展?
近40年来,表面等离子体共振(SPR)分析已被用于更好地了解表面固定化生物受体与感兴趣的分析物之间的结合相互作用强度。表面等离子体共振的优势,超过其他亲和感测方法,如Western blots和elisa方法,在于它有可能以无标记的方式揭示结合动力学。此外,表面等离子体共振的概念也被广泛应用于生物传感器的开发,利用其直接的分析格式,短的响应时间,简单的样品处理以及多路传感的可能性。由于表面等离子体共振能够在传感界面检测折射率的微小变化,特别是对于较大尺寸的分析物,如细胞(如细菌)、蛋白质、肽和寡核苷酸,因此必须增加达到高灵敏度的可能性。所有亲和方法所固有的挑战都需要进一步的研究,包括非特异性表面结合事件、质量运输限制、空间位阻以及在缺乏选择性分析物结合的情况下数据误解的风险。这篇观点文章致力于概述解决这些挑战的不同方法,例如,与荧光读出耦合,电化学传感,质谱分析以及最近将横向流动概念整合到表面等离子体共振中。其他等离子体方法,如局部表面等离子体共振(LSPR),表面增强拉曼光谱(SERS)将不会被详细考虑,因为这些技术现在已经有了自己的地位。
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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