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A versatile and customizable low-cost 3D-printed open standard for microscopic imaging

Benedict Diederich, René Lachmann, Swen Carlstedt, Barbora Maršíková, Haoran Wang, Xavier Uwurukundo, Alexander S. Mosig, Rainer Heintzmann

2020Nature Communications173 citationsDOIOpen Access PDF

Abstract

Modern microscopes used for biological imaging often present themselves as black boxes whose precise operating principle remains unknown, and whose optical resolution and price seem to be in inverse proportion to each other. With UC2 (You. See. Too.) we present a low-cost, 3D-printed, open-source, modular microscopy toolbox and demonstrate its versatility by realizing a complete microscope development cycle from concept to experimental phase. The self-contained incubator-enclosed brightfield microscope monitors monocyte to macrophage cell differentiation for seven days at cellular resolution level (e.g. 2 μm). Furthermore, by including very few additional components, the geometry is transferred into a 400 Euro light sheet fluorescence microscope for volumetric observations of a transgenic Zebrafish expressing green fluorescent protein (GFP). With this, we aim to establish an open standard in optics to facilitate interfacing with various complementary platforms. By making the content and comprehensive documentation publicly available, the systems presented here lend themselves to easy and straightforward replications, modifications, and extensions.

Topics & Concepts

MicroscopeFluorescence microscopeComputer scienceMicroscopyInterfacingModular designOpen sourceNanotechnologyZebrafishOptical microscope3D printingOpticsMaterials scienceComputer hardwareBiologyFluorescenceScanning electron microscopePhysicsSoftwareOperating systemGeneBiochemistryComposite materialAdvanced Fluorescence Microscopy TechniquesCell Image Analysis TechniquesSingle-cell and spatial transcriptomics
A versatile and customizable low-cost 3D-printed open standard for microscopic imaging | Litcius