Optical nanoscopy: from acquisition to analysis.

Annual Review of Biomedical Engineering
Travis J GouldJoerg Bewersdorf

Abstract

Recent advances in far-field microscopy have demonstrated that fluorescence imaging is possible at resolutions well below the long-standing diffraction limit. By exploiting photophysical properties of fluorescent probe molecules, this new class of methods yields a resolving power that is fundamentally diffraction unlimited. Although these methods are becoming more widely used in biological imaging, they must be complemented by suitable data analysis approaches if their potential is to be fully realized. Here we review the basic principles of diffraction-unlimited microscopy and how these principles influence the selection of available algorithms for data analysis. Furthermore, we provide an overview of existing analysis strategies and discuss their application.

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Citations

Sep 24, 2013·PloS One·Hans BlomHjalmar Brismar
Mar 1, 2014·Nature Methods·Hendrik DeschoutKevin Braeckmans
Jan 18, 2013·ELife·Travis J Gould, Joerg Bewersdorf
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Aug 11, 2015·Optics Letters·Xiang HaoJoerg Bewersdorf
Mar 7, 2020·Biomedical Optics Express·Marijn SiemonsLukas C Kapitein
Jun 1, 2013·Optics Letters·Travis J GouldJoerg Bewersdorf
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Jun 6, 2014·Chemical Reviews·Francois-Xavier TheilletPhilipp Selenko
Mar 10, 2020·Bioconjugate Chemistry·Yang Zhang, Françisco M Raymo

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Methods Mentioned

BETA
imaging techniques
light microscopy
confocal microscopy
Fluorescence
fluorescence correlation spectroscopy
imaging technique
electron microscopy

Software Mentioned

SLCA
Tar
Eos

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