Laser-based 3D cell printing for tissue engineering
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Lothar Koch
,
Andrea Deiwick
Abstract
Currently, different 3D printing techniques are investigated for printing biomaterials and living cells. An ambitious aim is the printing of fully functional tissue or organs. Furthermore, for manifold applications in biomedical research and in testing of pharmaceuticals or cosmetics, printed tissue could be a new method, partly substituting test animals. Here we describe a laser-based printing technique applied for the arrangement of vital cells in two and three-dimensional patterns and for tissue engineering. First printed tissue, tested in vitro and in vivo, and printing of cell patterns for investigating cell-cell interactions are presented.
Acknowledgments
The studies described here have been supported by Deutsche Forschungsgemeinschaft, SFB TransRegio 37, REBIRTH Cluster of Excellence (Exc62/1), and by Land Niedersachsen and Volkswagenstiftung in the Biofabrication for NIFE project.
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©2014 by De Gruyter
Artikel in diesem Heft
- Frontmatter
- Editorial
- Manufacturing meets biofabrication: Part 1
- Review
- Additive manufacturing of photosensitive hydrogels for tissue engineering applications
- Letter
- Laser-based 3D cell printing for tissue engineering
- Highlight
- Additive manufacturing of cell-loaded alginate enriched with alkaline phosphatase for bone tissue engineering application
- Highlight
- Nanoporous silica nanoparticles with spherical and anisotropic shape as fillers in dental composite materials
Artikel in diesem Heft
- Frontmatter
- Editorial
- Manufacturing meets biofabrication: Part 1
- Review
- Additive manufacturing of photosensitive hydrogels for tissue engineering applications
- Letter
- Laser-based 3D cell printing for tissue engineering
- Highlight
- Additive manufacturing of cell-loaded alginate enriched with alkaline phosphatase for bone tissue engineering application
- Highlight
- Nanoporous silica nanoparticles with spherical and anisotropic shape as fillers in dental composite materials
