Abstract
Nonlinear structured illumination microscopy (nSIM) is an effective approach for super-resolution wide-field fluorescence microscopy with a theoretically unlimited resolution. In nSIM, carefully designed, highly-contrasted illumination patterns are combined with the saturation of an optical transition to enable sub-diffraction imaging. While the technique proved useful for two-dimensional imaging, extending it to three-dimensions is challenging due to the fading of organic fluorophores under intense cycling conditions. Here, we present a compressed sensing approach that allows 3D sub-diffraction nSIM of cultured cells by saturating fluorescence excitation. Exploiting the natural orthogonality of speckles at different axial planes, 3D probing of the sample is achieved by a single two-dimensional scan. Fluorescence contrast under saturated excitation is ensured by the inherent high density of intensity minima associated with optical vortices in polarized speckle patterns. Compressed speckle microscopy is thus a simple approach that enables 3D super-resolved nSIM imaging with potentially considerably reduced acquisition time and photobleaching.
Highlights
Nonlinear structured illumination microscopy is an effective approach for superresolution wide-field fluorescence microscopy with a theoretically unlimited resolution
A regular diffuser could replace the spatial light modulator (SLM) but the latter allows a dynamic control of the size of the illuminating speckle pattern and of the intensity at the sample plane
The random wave entering the objective is circularly polarized in order to minimize the axial field at isotropic vortices of same handedness and so, to provide isotropic superresolution in transverse planes under saturated excitation conditions
Summary
Nonlinear structured illumination microscopy (nSIM) is an effective approach for superresolution wide-field fluorescence microscopy with a theoretically unlimited resolution. Fluorescence-signal-wasting is all the more detrimental under optical-saturation conditions, required to allow breaking the diffraction limit up to theoretically unlimited resolutions, in which case nonlinear photo-bleaching may occur[5,20]. Speckle patterns lying in different transverse planes are orthogonal relatively to the cross-correlation product (Supplementary Note 2), allowing axial discrimination of twodimensional objects[22,23]. This property exactly provides the random-projection-measurement configuration ideally suited for compressed imaging reconstruction[24,25], in particular for 3D imaging[26]. Super-resolution imaging capabilities are characterized using fluorescent nanobeads, and applied for imaging stained lysosomes in fixed cultured cells
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