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3D bioprinting of hepatocytes: core–shell structured co-cultures with fibroblasts for enhanced functionality

Rania Taymour, David Kilian, Tilman Ahlfeld, Michael Gelinsky, Anja Lode

2021Scientific Reports85 citationsDOIOpen Access PDF

Abstract

With the aim of understanding and recapitulating cellular interactions of hepatocytes in their physiological microenvironment and to generate an artificial 3D in vitro model, a co-culture system using 3D extrusion bioprinting was developed. A bioink based on alginate and methylcellulose (algMC) was first shown to be suitable for bioprinting of hepatocytes; the addition of Matrigel to algMC enhanced proliferation and morphology of them in monophasic scaffolds. Towards a more complex system that allows studying cellular interactions, we applied core-shell bioprinting to establish tailored 3D co-culture models for hepatocytes. The bioinks were specifically functionalized with natural matrix components (based on human plasma, fibrin or Matrigel) and used to co-print fibroblasts and hepatocytes in a spatially defined, coaxial manner. Fibroblasts acted as supportive cells for co-cultured hepatocytes, stimulating the expression of certain biomarkers of hepatocytes like albumin. Furthermore, matrix functionalization positively influenced both cell types in their respective compartments by enhancing their adhesion, viability, proliferation and function. In conclusion, we established a functional co-culture model with independently tunable compartments for different cell types via core-shell bioprinting. This provides the basis for more complex in vitro models allowing co-cultivation of hepatocytes with other liver-specific cell types to closely resemble the liver microenvironment.

Topics & Concepts

Core (optical fiber)3D bioprintingShell (structure)Cell biologyComputer scienceComputational biologyChemistryBiologyBiomedical engineeringMaterials scienceMedicineTissue engineeringTelecommunicationsComposite material3D Printing in Biomedical ResearchInnovative Microfluidic and Catalytic Techniques InnovationPluripotent Stem Cells Research
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