Time-lapse two-color 3D imaging of live cells with doubled resolution using structured illumination

Fiolka, Reto; Shao, Lin; Rego, E. Hesper; Davidson, Michael W.; Gustafsson, Mats

doi:10.1073/pnas.1119262109

Cited by 300 publications

(256 citation statements)

References 23 publications

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“…The first in vivo images obtained with TIRF-SIM were reported in 2009 16 achieving frame rates of 11 Hz to visualize tubulin and kinesin dynamics, and two color TIRF-SIM systems have been presented 17,18 . Most recently, a guide for the construction and use of a single color two-beam SIM system was presented featuring frame-rates of up to 18 Hz 19,20 .…”

Section: Introductionmentioning

confidence: 99%

A Guide to Structured Illumination TIRF Microscopy at High Speed with Multiple Colors

Young

Ströhl

Kaminski

2016

JoVE

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Optical super-resolution imaging with structured illumination microscopy (SIM) is a key technology for the visualization of processes at the molecular level in the chemical and biomedical sciences. Although commercial SIM systems are available, systems that are custom designed in the laboratory can outperform commercial systems, the latter typically designed for ease of use and general purpose applications, both in terms of imaging fidelity and speed. This article presents an in-depth guide to building a SIM system that uses total internal reflection (TIR) illumination and is capable of imaging at up to 10 Hz in three colors at a resolution reaching 100 nm. Due to the combination of SIM and TIRF, the system provides better image contrast than rival technologies. To achieve these specifications, several optical elements are used to enable automated control over the polarization state and spatial structure of the illumination light for all available excitation wavelengths. Full details on hardware implementation and control are given to achieve synchronization between excitation light pattern generation, wavelength, polarization state, and camera control with an emphasis on achieving maximum acquisition frame rate. A step-by-step protocol for system alignment and calibration is presented and the achievable resolution improvement is validated on ideal test samples. The capability for video-rate super-resolution imaging is demonstrated with living cells.

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Section: Introductionmentioning

confidence: 99%

A Guide to Structured Illumination TIRF Microscopy at High Speed with Multiple Colors

Young

Ströhl

Kaminski

2016

JoVE

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“…The key element common to these super-resolution techniques for breaking the diffraction limit is the use of the photoswitching property of fluorophores, which is realized by using various optical phenomena such as stimulated emission, cis-trans isomerization, triplet pumping [14] and saturated excitation (SAX) [15][16][17]. Structured illumination microscopy (SIM), while not breaking the confocal microscopy diffraction limit, is also well known as a high-resolution imaging technique which doubles the spatial resolution by overcoming the diffraction limit in classical wide-field fluorescence microscopy [18,19].…”

Section: Introductionmentioning

confidence: 99%

Saturated excitation of fluorescent proteins for subdiffraction-limited imaging of living cells in three dimensions

et al. 2013

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We report, for the first time, the saturated excitation (SAX) of fluorescent proteins for subdiffraction-limited imaging of living cells in three-dimensions. To achieve saturation, a bright yellow and green fluorescent protein (Venus and EGFP) that exhibits a strong nonlinear fluorescence response to the high excitation intensity at the laser focus is used. Harmonic demodulation of the fluorescence signal produced by a modulated excitation light extracts the nonlinear fluorescence signals. After constructing the image from the nonlinear components, we obtain fluorescence images of living cells with spatial resolution beyond the diffraction limit. We also applied linear deconvolution to SAX microscopy and found it effective in further enhancing the contrast of small intracellular structures in the SAX image, confirming the expansion of the optical transfer function in SAX microscopy.

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“…The imaging speed in SIM is limited by the speed with which the illumination pattern can be modulated and the camera speed [8] . A temporal resolution of 100 ms in 2D [9] , 4 s in 3D [10] and 8.5 s in multi-colour 3D [10] imaging (Figure 1) has been achieved in living cells at the 2-fold enhanced spatial resolution. The achieved spatiotemporal resolution allowed observation of clathrin coated vesicle dynamics such as splitting and fusion events as well as clathrin mediated endocytosis (Figure 1).…”

Section: (Saturated) Structured Illumination Microscopy -(S)simmentioning

confidence: 99%

Super‐Resolution Microscopy: Going Live and Going Fast

Lakadamyali

2013

ChemPhysChem

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Time-lapse two-color 3D imaging of live cells with doubled resolution using structured illumination

Cited by 300 publications

References 23 publications

A Guide to Structured Illumination TIRF Microscopy at High Speed with Multiple Colors

A Guide to Structured Illumination TIRF Microscopy at High Speed with Multiple Colors

Saturated excitation of fluorescent proteins for subdiffraction-limited imaging of living cells in three dimensions

Super‐Resolution Microscopy: Going Live and Going Fast

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