2022
DOI: 10.1016/j.bpj.2022.05.027
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Precision in iterative modulation enhanced single-molecule localization microscopy

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Cited by 14 publications
(14 citation statements)
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“…This integration leads to a remarkable enhancement in resolution, up to a factor of two, or equivalently, a reduction in the required photon budget for a given resolution by up to four times. A recent theoretical study [46] even suggests that, with advanced data analysis techniques, the resolution enhancement achievable with iSMLM could surpass the factor of two.…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…This integration leads to a remarkable enhancement in resolution, up to a factor of two, or equivalently, a reduction in the required photon budget for a given resolution by up to four times. A recent theoretical study [46] even suggests that, with advanced data analysis techniques, the resolution enhancement achievable with iSMLM could surpass the factor of two.…”
Section: Discussionmentioning
confidence: 99%
“…In the realm of SMLM, ISM directly enhances the accuracy of single-molecule localizations, thus significantly elevating the ultimate SMLM resolution. From a perspective rooted in physical optics, this mirrors the twofold increase in localization accuracy achieved through patterned illumination techniques like SIMPLE [18, 19], SIMFLUX [20], as well as others [21, 22]. However, ISM offers a substantial reduction in experimental complexity.…”
Section: Introductionmentioning
confidence: 99%
“…Sauer and colleagues recently summarized the three key factors determining image resolution in SMLM: i) localization precision (statistical scattering of the measured position coordinates), ii) localization accuracy (systematic deviation between the measured and true position) and iii) the labeling density ( Helmerich et al, 2022 ). The first of these factors has been the main focus of efforts for improving image resolution, via hardware, e.g., by combining improved structured illumination conditions with single-molecule detection ( Kalisvaart et al, 2022 ; Zhan et al, 2022 ), DNA-PAINT with STORM ( Cnossen et al, 2020 ), using cryo-SMLM and ad hoc software corrections ( Schneider et al, 2020 ; Hinterer et al, 2022 ), or via computational methods that enhance localization precision through engineering of the PSF or other approaches as applied to a single ( Shaw et al, 2022 ) ( Li M. et al, 2022 ) or multiple fluorophores (colocalization precision) ( Koyama-Honda et al, 2005 ; Donnert et al, 2007 ; Lemmer et al, 2009 ; Curthoys et al, 2013 ; Weisenburger et al, 2014 ; Georgieva et al, 2016 ; Willems and MacGillavry, 2022 ).…”
Section: Future Prospectsmentioning
confidence: 99%
“…Another limiting factor on the road to improving the resolution of superresolution microscopies is the size of the fluorophore proper. Last-generation nanoscopies like 2-D MINFLUX ( Balzarotti et al, 2017 ; Eilers et al, 2018 ; Masullo et al, 2021 ), cryogenic nanoscopy ( Furubayashi et al, 2019 ; Furubayashi et al, 2020 ), iterative modulation-enhanced SMLM ( Kalisvaart et al, 2022 ), improved structured-illumination microscopies ( Chen et al, 2018 ; Markwirth et al, 2019 ; Zhanghao et al, 2019 ; Mangeat et al, 2021 ; Qiao et al, 2021 ; Smith et al, 2021 ; Chen et al, 2022 ; Hunter et al, 2022 ; Zhan et al, 2022 ), new high-resolution DNA-PAINT modalities ( Schnitzbauer et al, 2017 ), 3-D MINFLUX ( Gwosch et al, 2020 ; Grabner et al, 2022 ; Gwosch et al, 2022 ) or MINSTED ( Weber et al, 2021 ) are now facing the need to introduce smaller probes to resolve structures at the molecular scale. Successful examples are provided by the recent work in which pyrrolysyl-tRNA synthetase and orthogonal tRNA were matched to introduce clickable amino acids into bacterial and mammalian cell proteins, accomplishing 3-D imaging of β-actin in filopodia with a precision of ∼2 nm ( Mihaila et al, 2022 ).…”
Section: Future Prospectsmentioning
confidence: 99%
“…The images contain molecule shapes blurred with the microscope emission pattern, or the point spread function (PSF), which can be experimentally designed and modelled to encode additional positional information in its shape 5,7,8 . The molecule positions are determined through maximum likelihood estimation (MLE) 9 or maximum a posteriori (MAP) estimation 10 of the position parameters within the point spread function (PSF) model. Therefore, creating a flexible PSF model that accurately represents the true experimental PSF is crucial for the ultimate localization accuracy and precision 11 .…”
Section: Introductionmentioning
confidence: 99%