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Dual color DMD-SIM by temperature-controlled laser wavelength matching

Mario Lachetta, Gerd Wiebusch, Wolfgang Hübner, Jan Schulte am Esch, Thomas Huser, Marcel Müller

2021Optics Express18 citationsDOIOpen Access PDF

Abstract

Structured illumination microscopy (SIM) is a fast and gentle super-resolution fluorescence imaging technique, featuring live-cell compatible excitation light levels and high imaging speeds. To achieve SIM, spatial modulation of the fluorescence excitation light is employed. This is typically achieved by interfering coherent laser beams in the sample plane, which are often created by spatial light modulators (SLMs). Digital micromirror devices (DMDs) are a form of SLMs with certain advantages, such as high speed, low cost and wide availability, which present certain hurdles in their implementation, mainly the blazed grating effect caused by the jagged surface structure of the tilted mirrors. Recent works have studied this effect through modelling, simulations and experiments, and laid out possible implementations of multi-color SIM imaging based on DMDs. Here, we present an implementation of a dual-color DMD based SIM microscope using temperature-controlled wavelength matching. By carefully controlling the output wavelength of a diode laser by temperature, we can tune two laser wavelengths in such a way that no opto-mechanical realignment of the SIM setup is necessary when switching between both wavelengths. This reduces system complexity and increases imaging speed. With measurements on nano-bead reference samples, as well as the actin skeleton and membrane of fixed U2OS cells, we demonstrate the capabilities of the setup.

Topics & Concepts

OpticsDigital micromirror deviceLaserMaterials scienceWavelengthGratingMicroscopeMicroscopyDiffraction gratingModulation (music)Light sheet fluorescence microscopyOptoelectronicsFluorescence-lifetime imaging microscopyLaser diodeSpatial light modulatorInterference (communication)PhysicsLaser scanningBeam splitterStray lightFluorescence microscopeSpatial frequencyAdaptive opticsExcitationSpatial filterSemiconductor laser theoryFluorescenceDeformable mirrorDiodeFiber Bragg gratingAdvanced Fluorescence Microscopy TechniquesAdvanced optical system designRandom lasers and scattering media