A 3D bioprinting system to produce human-scale tissue constructs with structural integrity

A new bioprinting system produces large tissue constructs with enough structural stability for surgical implantation. A challenge for tissue engineering is producing three-dimensional (3D), vascularized cellular constructs of clinically relevant size, shape and structural integrity. We present an in...

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Bibliographic Details
Published in:Nature biotechnology 2016-03, Vol.34 (3), p.312-319
Main Authors: Kang, Hyun-Wook, Lee, Sang Jin, Ko, In Kap, Kengla, Carlos, Yoo, James J, Atala, Anthony
Format: Article
Language:English
Subjects:
101/28
13/100
13/106
13/107
13/56
14/19
14/63
3-D technology
3D printing
631/61/2035
64/60
692/308
Agriculture
Biocompatible Materials - chemistry
Biodegradation
Bioinformatics
Biomedical Engineering/Biotechnology
Biomedicine
Bioprinting
Bioprinting - methods
Biotechnology
Humans
Hydrogels - chemistry
Life Sciences
Mandible - physiology
Nozzles
Nutrients
Polymers
Polymers - chemistry
Printing, Three-Dimensional
Technology application
Tissue engineering
Tissue Engineering - methods
Tissue Scaffolds
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Summary:A new bioprinting system produces large tissue constructs with enough structural stability for surgical implantation. A challenge for tissue engineering is producing three-dimensional (3D), vascularized cellular constructs of clinically relevant size, shape and structural integrity. We present an integrated tissue–organ printer (ITOP) that can fabricate stable, human-scale tissue constructs of any shape. Mechanical stability is achieved by printing cell-laden hydrogels together with biodegradable polymers in integrated patterns and anchored on sacrificial hydrogels. The correct shape of the tissue construct is achieved by representing clinical imaging data as a computer model of the anatomical defect and translating the model into a program that controls the motions of the printer nozzles, which dispense cells to discrete locations. The incorporation of microchannels into the tissue constructs facilitates diffusion of nutrients to printed cells, thereby overcoming the diffusion limit of 100–200 μm for cell survival in engineered tissues. We demonstrate capabilities of the ITOP by fabricating mandible and calvarial bone, cartilage and skeletal muscle. Future development of the ITOP is being directed to the production of tissues for human applications and to the building of more complex tissues and solid organs.
ISSN:1087-0156
1546-1696
DOI:10.1038/nbt.3413