Gigantic optical non‐linearities from nanoparticle‐enhanced molecular probes with potential for selectively imaging the structure and physiology of nanometric regions in cellular systems

G. Peleg, A. Lewis, O. Bouevitch, L. Loew, D. Parnas, M. Linial
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引用次数: 26

Abstract

The requirement to functionally probe biological structures, with ever increasing selectivity and three-dimensional resolution is a frontier area in microscopy. Non-linear optics has a unique potential in this regard with numerous studies focused on the potential of three-dimensional imaging with super-resolution. In this paper we demonstrate that non-linear optical phenomena, such as second harmonic (SH) generation, which is very sensitive to the membrane potential, can be locally enhanced by complexing or approaching a SH generating molecular probe to a nanoantenna of a silver or gold nanoparticle. This gives complexes with gigantic optical non-linearities. These contrast enhancing non-linear optical complexes have the potential to be directed selectively to specific nanometric regions in cells in order to report on alterations on the structure and the function in such regions while overcoming the inherent inefficiency of non-linear optical interactions.
纳米粒子增强分子探针的巨大光学非线性,具有选择性成像细胞系统中纳米区域结构和生理的潜力
随着选择性和三维分辨率的不断提高,功能性探测生物结构的需求是显微镜学的前沿领域。非线性光学在这方面具有独特的潜力,许多研究都集中在超分辨率三维成像的潜力上。在本文中,我们证明了非线性光学现象,如二次谐波(SH)的产生,对膜电位非常敏感,可以通过络合或接近产生SH的分子探针到银或金纳米粒子的纳米天线来局部增强。这就产生了具有巨大光学非线性的复合体。这些增强对比度的非线性光学配合物有可能被选择性地定向到细胞中的特定纳米区域,以便在克服非线性光学相互作用固有的低效率的同时,报告这些区域的结构和功能的变化。
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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