生物学与医学中的表面等离子体光散射:新的传感方法、愿景与展望
Plasmon light scattering in biology and medicine: new sensing approaches, visions and perspectives.
作者信息
Aslan Kadir, Lakowicz Joseph R, Geddes Chris D
机构信息
Institute of Fluorescence, Laboratory for Advanced Medical Plasmonics, Medical Biotechnology Center, University of Maryland Biotechnology Institute, Baltimore, MD 21201, USA.
出版信息
Curr Opin Chem Biol. 2005 Oct;9(5):538-44. doi: 10.1016/j.cbpa.2005.08.021.
Abstract
Surface plasmons are collective oscillations of free electrons at metallic surfaces. These oscillations can give rise to the intense colors of solutions of plasmon resonance nanoparticles and/or very intense scattering. While the use of plasmonic particle absorption based bioaffinity sensing is now widespread throughout biological research, the use of their scattering properties is relatively ill explored. We refer to the use, utility and control of surface plasmons as plasmonics. In this review and forward-looking article, we discuss the current opinions and uses of plasmonics, as well as speculate on areas of future research. These include the use of plasmon scatter for long-range immunosensing and macromolecular conformation studies, as well as the ability to Stokes shift plasmon scatter, a plasmonics phenomenon recently referred to as metal-enhanced fluorescence.
摘要
表面等离子体激元是金属表面自由电子的集体振荡。这些振荡可导致等离子体共振纳米颗粒溶液产生强烈颜色和/或非常强烈的散射。虽然基于等离子体颗粒吸收的生物亲和传感目前在整个生物学研究中广泛使用,但其散射特性的应用相对较少被探索。我们将表面等离子体激元的应用、效用和控制称为等离子体激元学。在这篇综述和前瞻性文章中,我们讨论了等离子体激元学的当前观点和应用,并对未来研究领域进行了推测。这些包括将等离子体散射用于远程免疫传感和大分子构象研究,以及对等离子体散射进行斯托克斯位移的能力,这是一种最近被称为金属增强荧光的等离子体激元学现象。
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