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Liquid-embedded (bio)printing of alginate-free, standalone, ultrafine, and ultrathin-walled cannular structures.

Guosheng TangZeyu LuoLiming LianJie GuoSushila MaharjanCarlos Ezio Garciamendez-MijaresMian WangWanlu LiZhenrui ZhangDi WangMaobin XieHossein RavanbakhshCuiping ZhouXiao KuangYingying HouXiyong YuYu Shrike Zhang
Published in: Proceedings of the National Academy of Sciences of the United States of America (2023)
While there has been considerable success in the three-dimensional bioprinting of relatively large standalone filamentous tissues, the fabrication of solid fibers with ultrafine diameters or those cannular featuring ultrathin walls remains a particular challenge. Here, an enabling strategy for (bio)printing of solid and hollow fibers whose size ranges could be facilely adjusted across a broad spectrum, is reported, using an aqueous two-phase embedded (bio)printing approach combined with specially designed cross-linking and extrusion methods. The generation of standalone, alginate-free aqueous architectures using this aqueous two-phase strategy allowed freeform patterning of aqueous bioinks, such as those composed of gelatin methacryloyl, within the immiscible aqueous support bath of poly(ethylene oxide). Our (bio)printing strategy revealed the fabrication of standalone solid or cannular structures with diameters as small as approximately 3 or 40 μ m, respectively, and wall thicknesses of hollow conduits down to as thin as <5 μ m. With cellular functions also demonstrated, we anticipate the methodology to serve as a platform that may satisfy the needs for the different types of potential biomedical and other applications in the future, especially those pertaining to cannular tissues of ultrasmall diameters and ultrathin walls used toward regenerative medicine and tissue model engineering.
Keyphrases
  • ionic liquid
  • metal organic framework
  • tissue engineering
  • gene expression
  • particulate matter
  • high resolution
  • risk assessment
  • high throughput
  • single cell
  • human health
  • liquid chromatography