1. Triple-Color STED Nanoscopy: Sampling Absorption Spectra Differences for Efficient Linear Species Unmixing
- Author
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Mariano Gonzalez Pisfil, Marcelle König, Benedikt Krämer, Rainer Erdmann, Felix Koberling, Sumeet Rohilla, and Matthias Patting
- Subjects
Physics ,Digital image correlation ,Microscopy, Confocal ,010304 chemical physics ,STED microscopy ,Nanosecond ,010402 general chemistry ,01 natural sciences ,Fluorescence ,0104 chemical sciences ,Surfaces, Coatings and Films ,Wavelength ,Microscopy, Fluorescence ,0103 physical sciences ,Materials Chemistry ,Fluorescence microscope ,Stimulated emission ,Physical and Theoretical Chemistry ,Biological system ,Absorption (electromagnetic radiation) ,Algorithms - Abstract
Stimulated emission depletion (STED) in confocal fluorescence microscopy enables a visualization of biological structures within cells far below the optical diffraction limit. To meet the demand in the field for simultaneous investigations of multiple species within a cell, a couple of different STED techniques have been proposed, each with their own challenges. By systemically exploiting spectral differences in the absorption of fluorescent labels, we present a novel, beneficial approach to multispecies STED nanoscopy. By using three excitation wavelengths in nanosecond pulsed interleaved excitation (PIE) mode, we probe quasi simultaneously multiple species with fluorescent labels having absorption maxima as close as 13 nm. The acquired image is decomposed into its single species contributions by application of a linear unmixing algorithm based on present reference patterns. For multispecies images containing single species regions, we introduce the image correlation map (ICM). Here, the single species regions easily can be identified in order to generate the necessary single species reference patterns. This avoids the otherwise cumbersome and artifact prone preparation and recording of additional reference samples. The power of the proposed imaging scheme persists in species separation quality at high speed shown for up to three species with established reference samples and dyes commonly used for cellular STED imaging.
- Published
- 2021