A BOTTOM-UP METHOD TO BUILD 3D SCAFFOLDS WITH PREDEFINED VASCULAR NETWORK

Tissue engineering is a promising approach to regenerate transplantable tissue or organ substitutes in vitro. However, the existing methods are based on seeding cells on macroscale polymer scaffolds, which are associated with several challenges including limited control over cell microenvironment, limited nutrient diffusion, directed cell alignment. The emerging bottom-up tissue engineering methods hold great potential to address these challenges by assembling building blocks into complex 3D tissue constructs. In this study, we developed a layer-by-layer assembly approach to recreate 3D cell-laden constructs. Our experiment showed the predefined channels form a vascular system and help the transplant cells to transport the requirement of culture cells in early case of cells attaching and growing up. It is an original concept to demonstrate the feasibility of forming a network with a vascular geometry in a biocompatible polymer and fabricated different scaffold with different cells. The concept was developed to create a complete branching vascular circulation in 3D on surface of mixture of chitosan and gelatin structures and pre-define the structure of channel for culturing smooth muscle for controlling the SMC growing up as smooth muscle fiber.

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