Machine learning assisted interferometric structured illumination microscopy for dynamic biological imaging.
Edward N WardLisa HeckerCharles N ChristensenJacob R LambMeng LuLuca MascheroniChyi Wei ChungAnna WangChristopher J RowlandsGabriele S Kaminski SchierleClemens F KaminskiPublished in: Nature communications (2022)
Structured Illumination Microscopy, SIM, is one of the most powerful optical imaging methods available to visualize biological environments at subcellular resolution. Its limitations stem from a difficulty of imaging in multiple color channels at once, which reduces imaging speed. Furthermore, there is substantial experimental complexity in setting up SIM systems, preventing a widespread adoption. Here, we present Machine-learning Assisted, Interferometric Structured Illumination Microscopy, MAI-SIM, as an easy-to-implement method for live cell super-resolution imaging at high speed and in multiple colors. The instrument is based on an interferometer design in which illumination patterns are generated, rotated, and stepped in phase through movement of a single galvanometric mirror element. The design is robust, flexible, and works for all wavelengths. We complement the unique properties of the microscope with an open source machine-learning toolbox that permits real-time reconstructions to be performed, providing instant visualization of super-resolved images from live biological samples.
Keyphrases
- high resolution
- high speed
- machine learning
- single molecule
- atomic force microscopy
- randomized controlled trial
- optical coherence tomography
- deep learning
- magnetic resonance imaging
- mass spectrometry
- magnetic resonance
- label free
- fluorescence imaging
- electronic health record
- convolutional neural network
- single cell