Strong signal increase in STED fluorescence microscopy by imaging regions of subdiffraction extent

Göttfert, Fabian; Pleiner, Tino; Heine, J.; Westphal, Volker; Görlich, Dirk; Sahl, Steffen J.; Hell, Stefan W.

doi:10.1073/pnas.1621495114

Cited by 100 publications

(98 citation statements)

References 39 publications

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“…The 2D and 3D DyMIN STED fluorescence nanoscopy was demonstrated with a microscope setup extended from the one previously described in ref. 11. For sample preparation of rat hippocampal neurons (Fig.…”

Section: Methodsmentioning

confidence: 99%

“…It enables the recording of many more frames of the respective sample region and/or imaging at higher resolutions, since a higher STED intensity can be applied, albeit at the expense that neighboring areas are potentially negatively affected (11).…”

Section: Significancementioning

confidence: 99%

“…But the fluorophores, as they are located near the minimum, do not experience the high intensity of the doughnut crest. This is exactly the rationale behind MINFIELD (11), but here the dynamic probing and adjustment of the STED intensity lifts the limitation of small scan fields, while it still avoids scanning a fullpower doughnut over the whole sample.…”

Section: Significancementioning

confidence: 99%

“…In RESCue, judgment of a region to be empty is followed by immediate shutdown of all beams at scan positions that are not occupied by fluorophores. Finally, a method called MINFIELD (11) was recently presented, which works by limiting the scan field to a region of about the same size as the doughnut minimum "valley." This avoids scanning the high-intensity crests over the fluorophores, significantly reducing their bleaching.…”

mentioning

confidence: 99%

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Adaptive-illumination STED nanoscopy

Heine

Reuß

Harke

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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144

147

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The concepts called STED/RESOLFT superresolve features by a light-driven transfer of closely packed molecules between two different states, typically a nonfluorescent "off" state and a fluorescent "on" state at well-defined coordinates on subdiffraction scales. For this, the applied light intensity must be sufficient to guarantee the state difference for molecules spaced at the resolution sought. Relatively high intensities have therefore been applied throughout the imaging to obtain the highest resolutions. At regions where features are far enough apart that molecules could be separated with lower intensity, the excess intensity just adds to photobleaching. Here, we introduce DyMIN (standing for Dynamic Intensity Minimum) scanning, generalizing and expanding on earlier concepts of RESCue and MINFIELD to reduce sample exposure. The principle of DyMIN is that it only uses as much on/ off-switching light as needed to image at the desired resolution. Fluorescence can be recorded at those positions where fluorophores are found within a subresolution neighborhood. By tuning the intensity (and thus resolution) during the acquisition of each pixel/voxel, we match the size of this neighborhood to the structures being imaged. DyMIN is shown to lower the dose of STED light on the scanned region up to ∼20-fold under common biological imaging conditions, and >100-fold for sparser 2D and 3D samples. The bleaching reduction can be converted into accordingly brighter images at <30-nm resolution.fluorescence nanoscopy | superresolution | STED microscopy | photobleaching | adaptive illumination

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Section: Methodsmentioning

confidence: 99%

Section: Significancementioning

confidence: 99%

Section: Significancementioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Adaptive-illumination STED nanoscopy

Heine

Reuß

Harke

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

144

147

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“…To simplify the system, only one SLM was adopted to modulate the same beam twice, so as to produce 3D depletion on the basis of the particular polarization‐response characteristic of SLM . To further improve the 3D resolution of STED, which is mainly limited by photobleaching and photodamage, the focal intensity distributions were adaptively controlled by the SLM to reduce the overall illumination dose and achieve ≈60‐nm axial resolution . Axial depletion can also be used for other similar point scanning techniques, such as fluorescence emission difference microscopy, to increase their resolution …”

Section: Methods For Axial Srfmmentioning

confidence: 99%

Breaking the Axial Diffraction Limit: A Guide to Axial Super‐Resolution Fluorescence Microscopy

Liu

Toussaint

Okoro

et al. 2018

Laser & Photonics Reviews

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Optical microscopy is a powerful tool for understanding the fundamentals of the microscopic world. However, for centuries its resolving ability remained limited by the optical diffraction limit. Super‐resolution fluorescence microscopy (SRFM) has been introduced to break the diffraction limit and significantly expand the fields in which optical microscopy can be applied. Unfortunately, SRFM contributes little towards axial resolution enhancement, rendering observation of the axial and three‐dimensional structures of biological tissues difficult; this may yield a misunderstanding of intracellular interactions. Based on the existing literature, the development of axial SRFM is still behind that of lateral SRFM. In light of this, this Review presents a comprehensive summary of the principles, development, characteristics, and applications of existing techniques for improving the axial resolution. This Review will provide a guide to researchers and promote further development of related technology.

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Stimulated emission depletion microscopy for biological imaging in four dimensions: A review

2021

Microscopy Res & Technique

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Stimulated emission depletion (STED) microscopy allows high lateral and axial resolution, long term imaging in living cells. Here we review recent technical advances in STED microscopy, with emphasis on resolution and measurement range of XYZt four dimensions. Different STED technical advances and novel STED probes are discussed with their respective application in biological subcellular imaging. This review may serve as a practical guide for choosing a suitable approach to the advanced STED super‐resolution imaging.

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Strong signal increase in STED fluorescence microscopy by imaging regions of subdiffraction extent

Cited by 100 publications

References 39 publications

Adaptive-illumination STED nanoscopy

Adaptive-illumination STED nanoscopy

Breaking the Axial Diffraction Limit: A Guide to Axial Super‐Resolution Fluorescence Microscopy

Stimulated emission depletion microscopy for biological imaging in four dimensions: A review

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