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  • Design and Development of a Three-Dimensional Printing High-Throughput Melt Electrowriting Technology Platform

    Author(s)
    Wunner, Felix M
    Eggert, Sebastian
    Maartens, Joachim
    Bas, Onur
    Dalton, Paul D
    De-Juan-Pardo, Elena M
    Hutmacher, Dietmar W
    Griffith University Author(s)
    Hutmacher, Dietmar W.
    Year published
    2019
    Metadata
    Show full item record
    Abstract
    Three-dimensionally (3D) printed scaffolds and cell culture lattices with microscale features are increasingly being used in tissue engineering and regenerative medicine. One additive manufacturing technology used to design and fabricate such structures is melt electrowriting (MEW), a process which needs to be scaled in production to effectively translate to industrial applications. In this study, a scale-up printer, designed with eight simultaneously extruding heads, is constructed and validated. Importantly, identical structures could be fabricated using parameters developed from a single-head system, therefore establishing ...
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    Three-dimensionally (3D) printed scaffolds and cell culture lattices with microscale features are increasingly being used in tissue engineering and regenerative medicine. One additive manufacturing technology used to design and fabricate such structures is melt electrowriting (MEW), a process which needs to be scaled in production to effectively translate to industrial applications. In this study, a scale-up printer, designed with eight simultaneously extruding heads, is constructed and validated. Importantly, identical structures could be fabricated using parameters developed from a single-head system, therefore establishing a MEW printer ecosystem that allows for direct upscaling from laboratory research. The successful transfer to vertically mounted collectors produced homogeneous reproducible scaffolds with identical morphologies and fiber diameters. These proof-of-concept experiments also show that MEW is capable of large-scale fabrication, successfully demonstrated by manufacturing 780 × 780-mm sheets of scaffolds/lattices. This study demonstrates that upscaling MEW can be realized by multiplying the number of print heads, while vertical mounting of the collector significantly reduces the MEW footprint. Additionally, economic aspects were considered during the development and costly components, such as the x, y, and z linear axes, were minimized. Herein, a systems engineering approach for the development of a high-throughput MEW technology platform is presented for the first time.
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    Journal Title
    3D Printing and Additive Manufacturing
    Volume
    6
    Issue
    2
    DOI
    https://doi.org/10.1089/3dp.2017.0149
    Subject
    Biomedical engineering
    Materials engineering
    Science & Technology
    Technology
    Engineering, Manufacturing
    Materials Science, Multidisciplinary
    Engineering
    Publication URI
    http://hdl.handle.net/10072/387142
    Collection
    • Journal articles

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