DeepSTORM3D: dense 3D localization microscopy and PSF design by deep learning

Nehme, Elias; Freedman, Daniel Z.; Gordon, Racheli; Ferdman, Boris; Weiss, Lucien E.; Alalouf, Onit; Naor, Tal; Orange, Reut; Michaeli, Tomer; Shechtman, Yoav

doi:10.1038/s41592-020-0853-5

Cited by 224 publications

(189 citation statements)

References 51 publications

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“…It has also provided solutions to other, less-routine, computational tasks. For example, image restoration algorithms attempt to enhance image quality by inferring high-quality images from low-quality data (Weigert et al, 2018) using a variety of strategies, such as by taking advantage of structural redundancy in an image to reconstruct high-quality super-resolution images from under-sampled localization microscopy data (Ouyang et al, 2018), or by performing point spread function engineering for single-molecule localization (Nehme et al, 2020). Other applications include the inference of intracellular organelle localization from labelfree images and the mapping of different cell microscopy modalities onto one another (Christiansen et al, 2018;Ounkomol et al, 2018), with potential applications including high-content screening (Cheng et al, 2021) and the prediction of the functional cell state, such as stages of the cell cycle or disease progression (Buggenthin et al, 2017;Eulenberg et al, 2017;Yang et al, 2020;Zaritsky et al, 2020 preprint).…”

Section: Data Science In Cell Biologymentioning

confidence: 99%

Data science in cell imaging

Driscoll

Zaritsky

2021

Journal of Cell Science

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Cell imaging has entered the ‘Big Data’ era. New technologies in light microscopy and molecular biology have led to an explosion in high-content, dynamic and multidimensional imaging data. Similar to the ‘omics’ fields two decades ago, our current ability to process, visualize, integrate and mine this new generation of cell imaging data is becoming a critical bottleneck in advancing cell biology. Computation, traditionally used to quantitatively test specific hypotheses, must now also enable iterative hypothesis generation and testing by deciphering hidden biologically meaningful patterns in complex, dynamic or high-dimensional cell image data. Data science is uniquely positioned to aid in this process. In this Perspective, we survey the rapidly expanding new field of data science in cell imaging. Specifically, we highlight how data science tools are used within current image analysis pipelines, propose a computation-first approach to derive new hypotheses from cell image data, identify challenges and describe the next frontiers where we believe data science will make an impact. We also outline steps to ensure broad access to these powerful tools – democratizing infrastructure availability, developing sensitive, robust and usable tools, and promoting interdisciplinary training to both familiarize biologists with data science and expose data scientists to cell imaging.

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Section: Data Science In Cell Biologymentioning

confidence: 99%

Data science in cell imaging

Driscoll

Zaritsky

2021

Journal of Cell Science

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“…Our study lays the foundation for further refinement and optimization of the presented correlative conventional fluorescence and PALM imaging technique and its application to study a myriad of different chromatin loci. For instance, extending this technique to 3D to track loci for longer periods of time and to extend the lifetime of the conventional signal would extend the imaging time of loci and result in an improved spatial and temporal resolution 15,28,44,53,54 . In addition, orthogonal RNA binding proteins and/or CRISPR-Cas proteins could be applied to enable simultaneous multicolor imaging of different chromatin regions 14,[18][19][20] .…”

Section: Conclusion and Future Outlookmentioning

confidence: 99%

Characterizing Locus Specific Chromatin Structure and Dynamics with Correlative Conventional and Super Resolution imaging in living cells

Mehra

Adhikari

Banerjee

et al. 2021

Preprint

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The dynamic rearrangement of chromatin is critical for gene regulation, but mapping both the spatial organization of chromatin and its dynamics remains a challenge. Many structural conformations are too small to be resolved via conventional fluorescence microscopy and the long acquisition time of super-resolution PALM imaging precludes the structural characterization of chromatin below the optical diffraction limit in living cells due to chromatin motion. Here we develop a correlative conventional fluorescence and PALM imaging approach to quantitatively map time-averaged chromatin structure and dynamics below the optical diffraction limit in living cells. By assigning localizations to a locus as it moves, we reliably discriminate between bound and searching dCas9 molecules, whose mobility overlap. Our approach accounts for changes in DNA mobility and relates local chromatin motion to larger scale domain movement. In our experimental system, we show that compacted telomeres have a higher density of bound dCas9 molecules, but the relative motion of those molecules is more restricted than in less compacted telomeres. Correlative conventional and PALM imaging therefore improves the ability to analyze the mobility and time-averaged nanoscopic structural features of locus specific chromatin with single molecule precision and yields unprecedented insights across length and time scales.

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“…Overlapping signals from fluorophores can confound the analysis of STORM images, particularly for 3D imaging, and this is typically resolved by imaging fewer fluorophores per round -a tactic that precludes high-speed imaging. Yoav Shechtman's team at the Technion in Haifa, Israel, employed a deep-learning-based approach to overcome this difficult scenario 4 . They used their algorithm to engineer the point-spread function (PSF)the representation of a fluorophore's signal as generated by a microscope's detection system -to enable better discrimination of individual signals in 3D.…”

Section: Image Consultantsmentioning

confidence: 99%