金属增强单线态氧的产生：等离子体激元增强三重态产率的结果。

Metal-enhanced singlet oxygen generation: a consequence of plasmon enhanced triplet yields.

作者信息

Zhang Yongxia, Aslan Kadir, Previte Michael J R, Geddes Chris D

机构信息

Institute of Fluorescence, Laboratory for Advanced Medical Plasmonics, Medical Biotechnology Center, University of Maryland Biotechnology Institute, 725 West Lombard St, Baltimore, MD 21201, USA.

出版信息

J Fluoresc. 2007 Jul;17(4):345-9. doi: 10.1007/s10895-007-0196-y. Epub 2007 May 18.

DOI:10.1007/s10895-007-0196-y

PMID:17510778

Abstract

In this Rapid Communication, we report the first observation of Metal-Enhanced singlet oxygen generation (ME(1)O(2)). Rose Bengal in close proximity to Silver Island Films (SiFs) can generate more singlet oxygen, a three-fold increase observed, as compared to an identical glass control sample but containing no silver. The enhanced absorption of the photo-sensitizer, due to coupling to silver surface plasmons, facilitates enhanced singlet oxygen generation. The singlet oxygen yield can potentially be adjusted by modifying the choice of MEF (Metal-Enhanced Fluorescence) & MEP (Metal Enhance Phosphorescence) parameters, such as distance dependence for plasmon coupling and wavelength emission of the coupling fluorophore. This is a most helpful observation in understanding the interactions between plasmons and lumophores, and this approach may well be of significance for singlet oxygen based clinical therapy.

摘要

在本快速通讯中，我们报告了对金属增强单线态氧生成（ME(1)O(2)）的首次观察结果。与不含银的相同玻璃对照样品相比，靠近银岛膜（SiFs）的孟加拉玫瑰红能产生更多的单线态氧，观察到增加了三倍。由于与银表面等离子体激元耦合，光敏剂的吸收增强，这有助于增强单线态氧的生成。通过改变金属增强荧光（MEF）和金属增强磷光（MEP）参数的选择，如等离子体激元耦合的距离依赖性和耦合荧光团的波长发射，可以潜在地调节单线态氧产率。这对于理解等离子体激元和发光体之间的相互作用是一个非常有帮助的观察结果，并且这种方法对于基于单线态氧的临床治疗可能具有重要意义。

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金属增强单线态氧的产生：等离子体激元增强三重态产率的结果。

Metal-enhanced singlet oxygen generation: a consequence of plasmon enhanced triplet yields.

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