Mapping molecular statistics with balanced super-resolution optical fluctuation imaging (bSOFI)

Geissbuehler, Stefan; Bocchio, Noelia L.; Dellagiacoma, Claudio; Berclaz, Corinne; Leutenegger, Marcel; Lasser, Theo

doi:10.1186/2192-2853-1-4

Cited by 154 publications

(249 citation statements)

References 15 publications

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“…As with 3B, this method is computationally demanding and one group reported taking a whole day to process a 100 lm 2 region [83]. Stochastic Optical Fluctuation Imaging (SOFI) is capable of doubling the resolution with a standard widefield microscope (200 frames) [86] and achieving 80 nm resolution with a TIRF microscope with low laser powers (5000 frames) [87]. The virtual removal of background and out-of-focus light in SOFI allows it to generate optically sectioned z-stacks, and a Matlab SOFI package is freely available SOFI package [88].…”

Section: Impact Of Analysis Algorithms On Acquisition Speedmentioning

confidence: 99%

PALM and STORM: Into large fields and high-throughput microscopy with sCMOS detectors

Almada¹,

Culley²,

Henriques³

2015

Methods

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Hardware sCMOS Homogenization a b s t r a c tSingle Molecule Localization Microscopy (SMLM) techniques such as Photo-Activation Localization Microscopy (PALM) and Stochastic Optical Reconstruction Microscopy (STORM) enable fluorescence microscopy super-resolution: the overcoming of the resolution barrier imposed by the diffraction of light. These techniques are based on acquiring hundreds or thousands of images of single molecules, locating them and reconstructing a higher-resolution image from the high-precision localizations. These methods generally imply a considerable trade-off between imaging speed and resolution, limiting their applicability to high-throughput workflows. Recent advancements in scientific Complementary Metal-Oxide Semiconductor (sCMOS) camera sensors and localization algorithms reduce the temporal requirements for SMLM, pushing it toward high-throughput microscopy. Here we outline the decisions researchers face when considering how to adapt hardware on a new system for sCMOS sensors with high-throughput in mind.

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Section: Impact Of Analysis Algorithms On Acquisition Speedmentioning

confidence: 99%

PALM and STORM: Into large fields and high-throughput microscopy with sCMOS detectors

Almada¹,

Culley²,

Henriques³

2015

Methods

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show abstract

“…Compared with PALM, this technique tolerates higher fluorophore densities or higher activation rates, resulting in an improved temporal resolution 11 . Additionally, an extension called balanced SOFI (bSOFI) can be used to determine the fluorophore on-time ratio, which allows to estimate of the fluorophore density 12 . In previous work, we investigated the complementarity of PALM and SOFI by applying both techniques to the same sequence of camera frames 13 .…”

Section: Introductionmentioning

confidence: 99%

Combining PALM and SOFI for quantitative imaging of focal adhesions in living cells

Deschout

Lozano-Pérez

Sharipov

et al. 2017

Single Molecule Spectroscopy and Superresolution Imaging X

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Focal adhesions are complicated assemblies of hundreds of proteins that allow cells to sense their extracellular matrix and adhere to it. Although most focal adhesion proteins have been identified, their spatial organization in living cells remains challenging to observe. Photo-activated localization microscopy (PALM) is an interesting technique for this purpose, especially since it allows estimation of molecular parameters such as the number of fluorophores. However, focal adhesions are dynamic entities, requiring a temporal resolution below one minute, which is difficult to achieve with PALM. In order to address this problem, we merged PALM with super-resolution optical fluctuation imaging (SOFI) by applying both techniques to the same data. Since SOFI tolerates an overlap of single molecule images, it can improve the temporal resolution compared to PALM. Moreover, an adaptation called balanced SOFI (bSOFI) allows estimation of molecular parameters, such as the fluorophore density. We therefore performed simulations in order to assess PALM and SOFI for quantitative imaging of dynamic structures. We demonstrated the potential of our PALM-SOFI concept as a quantitative imaging framework by investigating moving focal adhesions in living cells.

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“…5, the SOFI technique can be employed on various platforms, e.g., wide-field, total internal reflection fluorescence (TIRF), and spinningdisk confocal microscopes (Dertinger et al, 2013). Geissbuehler et al (2012) proposed balanced SOFI (bSOFI) combining multiple SOFI orders to improve spatial resolution and alleviate reconstruction artifacts. Zeng et al (2015) proposed joint tagging SOFI (JT-SOFI) to achieve fast, high-fidelity super-resolution imaging.…”

Section: Super-resolution Optical Fluctuation Imaging Microscopymentioning

confidence: 99%

Computational methods in super-resolution microscopy

Zeng

Xie

Chen

et al. 2017

Frontiers Inf Technol Electronic Eng

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Abstract:The broad applicability of super-resolution microscopy has been widely demonstrated in various areas and disciplines. The optimization and improvement of algorithms used in super-resolution microscopy are of great importance for achieving optimal quality of super-resolution imaging. In this review, we comprehensively discuss the computational methods in different types of super-resolution microscopy, including deconvolution microscopy, polarization-based super-resolution microscopy, structured illumination microscopy, image scanning microscopy, super-resolution optical fluctuation imaging microscopy, single-molecule localization microscopy, Bayesian super-resolution microscopy, stimulated emission depletion microscopy, and translation microscopy. The development of novel computational methods would greatly benefit super-resolution microscopy and lead to better resolution, improved accuracy, and faster image processing.

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Mapping molecular statistics with balanced super-resolution optical fluctuation imaging (bSOFI)

Cited by 154 publications

References 15 publications

PALM and STORM: Into large fields and high-throughput microscopy with sCMOS detectors

PALM and STORM: Into large fields and high-throughput microscopy with sCMOS detectors

Combining PALM and SOFI for quantitative imaging of focal adhesions in living cells

Computational methods in super-resolution microscopy

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