Content-Aware Image Restoration: Pushing the Limits of Fluorescence Microscopy

Weigert, Martin; Schmidt, Uwe; Boothe, Tobias; Müller, Andreas; Dibrov, Alexandr; Jain, Akanksha; Wilhelm, Benjamin G.; Schmidt, Deborah; Broaddus, Coleman; Culley, Siân; Rocha-Martins, Maurício; Segovia-Miranda, Fabián; Norden, Caren; Henriques, Ricardo; Zerial, Marino; Solimena, Michele; Rink, Jochen C.; Tomančák, Pavel; Royer, Loïc A.; Jug, Florian; Myers, Eugene W.

doi:10.1101/236463

Cited by 128 publications

(222 citation statements)

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“…maximum likelihood based) approaches constrained to positive density and considering the Poisson statistics of photon noise and the spatially varying variance may achieve better reconstruction results with enhanced signal to noise ratios. Especially dedicated regularisation, for example, based on the spatial Hessian matrix (Huang et al, 2018) or trained artificial neural networks (Weigert et al, 2018), can achieve significant SNR advantages, yet one may expect similar SNR scaling laws to apply.…”

Section: Noisementioning

confidence: 99%

Signal, noise and resolution in linear and nonlinear structured‐illumination microscopy

Ingerman

London

Heintzmann

et al. 2018

Journal of Microscopy

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Structured-illumination microscopy allows widefield fluorescence imaging with resolution beyond the classical diffraction limit. Its linear form extends resolution by a factor of two, and its nonlinear form by an in-principle infinite factor, the effective resolution in practice being determined by noise. In this paper, we analyse the noise properties and achievable resolution of linear and nonlinear 1D and 2D patterned SIM from a frequency-space perspective. We develop an analytical theory for a general case of linear or nonlinear fluorescent imaging, and verify the analytical calculations with numerical simulation for a special case where nonlinearity is produced by photoswitching of fluorescent labels. We compare the performance of two alternative implementations, using either two-dimensional (2D) illumination patterns or sequentially rotated one-dimensional (ID) patterns. We show that 1D patterns are advantageous in the linear case, and that in the nonlinear case 2D patterns provide a slight signal-to-noise advantage under idealised conditions, but perform worse than 1D patterns in the presence of nonswitchable fluorescent background.

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Section: Noisementioning

confidence: 99%

Signal, noise and resolution in linear and nonlinear structured‐illumination microscopy

Ingerman

London

Heintzmann

et al. 2018

Journal of Microscopy

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“…For higher noise levels however, deconvolution becomes much more difficult and most methods yield similar results. Weigert et al, 2017). y = Hx + n and consequently h(x; y) = Hx − y 2 2 .…”

Section: Resultsmentioning

confidence: 99%

“…These images are substantially different as they contain much more detailed and textured structures, which are harder to restore. A better approach for these methods is to train the CNN on actual EM data as in Weigert et al (2017). Typically, training a CNN from scratch requires large amounts of data and compute power.…”

Section: Resultsmentioning

confidence: 99%

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An overview of state‐of‐the‐art image restoration in electron microscopy

Roels

Aelterman

Luong

et al. 2018

Journal of Microscopy

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In Life Science research, electron microscopy (EM) is an essential tool for morphological analysis at the subcellular level as it allows for visualization at nanometer resolution. However, electron micrographs contain image degradations such as noise and blur caused by electromagnetic interference, electron counting errors, magnetic lens imperfections, electron diffraction, etc. These imperfections in raw image quality are inevitable and hamper subsequent image analysis and visualization. In an effort to mitigate these artefacts, many electron microscopy image restoration algorithms have been proposed in the last years. Most of these methods rely on generic assumptions on the image or degradations and are therefore outperformed by advanced methods that are based on more accurate models. Ideally, a method will accurately model the specific degradations that fit the physical acquisition settings. In this overview paper, we discuss different electron microscopy image degradation solutions and demonstrate that dedicated artefact regularisation results in higher quality restoration and is applicable through recently developed probabilistic methods.

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“…Recent publications using deep learning for reconstruction of fluorescence microscopy images (135,136) hold huge promise for the future. Such algorithms can reconstruct high quality images from noisy raw images acquired at low illumination levels.…”

Section: Outcomementioning

confidence: 99%