Three-dimensional direct cell bioprinting for tissue engineering.

Bioprinting is a relatively new technology where living cells with or without biomaterials are printed layer-by-layer in order to create three-dimensional (3D) living structures. In this article, novel bioprinting methodologies are developed to fabricate 3D biological structures directly from computer models using live multicellular aggregates. Multicellular aggregates made out of at least two cell types from fibroblast, endothelial and smooth muscle cells are prepared and optimized. A novel bioprinting approach is proposed in order to continuously extrude cylindrical multicellular aggregates through the bioprinter's glass microcapillaries. The multicellular aggregates are first aspirated into a capillary and then compressed to form a continuous cylindrical multicellular bioink. To overcome surface tension-driven droplet formation, the required compression ratio is calculated. Based on the developed bioprinting strategies, multicellular aggregates and their support structures are bioprinted to form 3D tissue constructs with predefined shapes. The effect of the bioprinting process was examined for fusion, cell viability at different compression ratios, and f-actin cytoskeletal organization. The results show that the bioprinted 3D constructs fuse rapidly and have high cell viability after printing. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 2530-2544, 2017.

3D bioprinting of biomimetic aortic vascular constructs with self-supporting cells.

Cardiovascular diseases are the leading cause of deaths throughout the world. Vascular diseases are mostly treated with autografts and blood vessel transplantations. However, traditional grafting methods have several problems including lack of suitable harvest sites, additional surgical costs for harvesting procedure, pain, infection, lack of donors, and even no substitutes at all. Recently, tissue engineering and regenerative medicine approaches are used to regenerate damaged or diseased tissues. Most of the tissue engineering investigations have been based on the cell seeding into scaffolds by providing a suitable environment for cell attachment, proliferation, and differentiation. Because of the challenges such as difficulties in seeding cells spatially, rejection, and inflammation of biomaterials used, the recent tissue engineering studies focus on scaffold-free techniques. In this paper, the development of novel computer aided algorithms and methods are developed for 3D bioprinting of scaffold-free biomimetic macrovascular structures. Computer model mimicking a real human aorta is generated using imaging techniques and the proposed computational algorithms. An optimized three-dimensional bioprinting path planning are developed with the proposed self-supported model. Mouse embryonic fibroblast (MEF) cell aggregates and support structures (hydrogels) are 3D bioprinted layer-by-layer according to the proposed self-supported method to form an aortic tissue construct.