Litcius/Paper detail

3D Bioprinting of Macroporous Materials Based on Entangled Hydrogel Microstrands

Benjamin Kessel, Mihyun Lee, Angela Bonato, Yann Tinguely, Enrico Tosoratti, Marcy Zenobi‐Wong

2020Advanced Science162 citationsDOIOpen Access PDF

Abstract

Hydrogels are excellent mimetics of mammalian extracellular matrices and have found widespread use in tissue engineering. Nanoporosity of monolithic bulk hydrogels, however, limits mass transport of key biomolecules. Microgels used in 3D bioprinting achieve both custom shape and vastly improved permissivity to an array of cell functions, however spherical-microbead-based bioinks are challenging to upscale, are inherently isotropic, and require secondary crosslinking. Here, bioinks based on high-aspect-ratio hydrogel microstrands are introduced to overcome these limitations. Pre-crosslinked, bulk hydrogels are deconstructed into microstrands by sizing through a grid with apertures of 40-100 µm. The microstrands are moldable and form a porous, entangled structure, stable in aqueous medium without further crosslinking. Entangled microstrands have rheological properties characteristic of excellent bioinks for extrusion bioprinting. Furthermore, individual microstrands align during extrusion and facilitate the alignment of myotubes. Cells can be placed either inside or outside the hydrogel phase with >90% viability. Chondrocytes co-printed with the microstrands deposit abundant extracellular matrix, resulting in a modulus increase from 2.7 to 780.2 kPa after 6 weeks of culture. This powerful approach to deconstruct bulk hydrogels into advanced bioinks is both scalable and versatile, representing an important toolbox for 3D bioprinting of architected hydrogels.

Topics & Concepts

3D bioprintingNanotechnologyMaterials scienceSelf-healing hydrogelsChemical engineeringChemistryBiomedical engineeringTissue engineeringPolymer chemistryMedicineEngineering3D Printing in Biomedical ResearchAdditive Manufacturing and 3D Printing TechnologiesInnovative Microfluidic and Catalytic Techniques Innovation