Sven C. Sidenstein scite author profile

A range of bright and photostable rhodamines and carbopyronines with absorption maxima in the range of λ=500–630 nm were prepared, and enabled the specific labeling of cytoskeletal filaments using HaloTag technology followed by staining with 1 μm solutions of the dye–ligand conjugates. The synthesis, photophysical parameters, fluorogenic behavior, and structure–property relationships of the new dyes are discussed. Light microscopy with stimulated emission depletion (STED) provided one‐ and two‐color images of living cells with an optical resolution of 40–60 nm.

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Hydroxylated Fluorescent Dyes for Live‐Cell Labeling: Synthesis, Spectra and Super‐Resolution STED

Butkevich

Belov

Kolmakov

et al. 2017

Chemistry A European J

106

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Hydroxylated rhodamines, carbopyronines, silico‐ and germanorhodamines with absorption maxima in the range of 530–640 nm were prepared and applied in specific labeling of living cells. The direct and high‐yielding entry to germa‐ and silaxanthones tolerates the presence of protected heteroatoms and may be considered for the syntheses of various sila‐ and germafluoresceins, as well as ‐rhodols. Application in stimulated emission depletion (STED) fluorescence microscopy revealed a resolution of 50–75 nm in one‐ and two‐color imaging of vimentin‐HaloTag fused protein and native tubulin. The established structure–property relationships allow for prediction of the spectral properties and the positions of spirolactone/zwitterion equilibria for the new analogues of rhodamines, carbo‐, silico‐, and germanorhodamines using simple additive schemes.

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Multicolour Multilevel STED nanoscopy of Actin/Spectrin Organization at Synapses

Sidenstein

D’Este

Böhm

et al. 2016

Sci Rep

108

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Superresolution fluorescence microscopy of multiple fluorophores still requires development. Here we present simultaneous three-colour stimulated emission depletion (STED) nanoscopy relying on a single STED beam at 620 nm. Toggling the STED beam between two or more power levels (“multilevelSTED”) optimizes resolution and contrast in all colour channels, which are intrinsically co-aligned and well separated. Three-colour recording is demonstrated by imaging the nanoscale cytoskeletal organization in cultured hippocampal neurons. The down to ~35 nm resolution identified periodic actin/betaII spectrin lattices along dendrites and spines; however, at presynaptic and postsynaptic sites, these patterns were found to be absent. Both our multicolour scheme and the 620 nm STED line should be attractive for routine STED microscopy applications.

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Coordinate-targeted fluorescence nanoscopy with multiple off states

et al. 2016

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Coordinate-Targeted Fluorescence Nanoscopy with Multiple Off-States

Danzl

Sidenstein

Gregor

et al. 2017

Biophysical Journal

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Many new, exciting imaging techniques have emerged during the last decade, providing significantly improved spatial resolution and contrast. However, this extra information comes at the cost of more photons required to illuminate the cell, which requires more time and energy and often damages biological structures. The smaller the structures to be investigated, the faster they usually move inside living cells, because of both Brownian motion and coordinated work of molecular motors. Therefore, alternative imaging approaches are necessary. In this talk I will present a novel technique called rotating coherent scattering (ROCS) microscopy. This imaging method is characterized by label-free, coherent imaging through scattering of a rotating laser beam, which reveals a variety of unexpectedly fast processes inside/of living cells. The technique operates at up to 100 Hz with a spatial resolution of currently 150nm, it can acquire thousands of images without loss in image quality and does not require postprocessing, such that the cells can be observed online.

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