3-D Printing in Organ Transplantation.
10.7599/hmr.2014.34.4.158
- Author:
Goeun LIM
1
;
Dongho CHOI
;
Eric B RICHARDSON
Author Information
1. Department of Surgery, Hanyang University College of Medicine, Seoul, Korea. crane87@hanyang.ac.kr
- Publication Type:Review
- Keywords:
Bioprinting;
Tissue engineering;
Imaging, Three-Dimensional
- MeSH:
Biocompatible Materials;
Bioengineering;
Bioprinting;
Extracellular Matrix;
Hope;
Imaging, Three-Dimensional;
Organ Transplantation*;
Regeneration;
Regenerative Medicine;
Stem Cell Research;
Stem Cells;
Tissue Engineering;
Transplants*;
Wound Healing
- From:Hanyang Medical Reviews
2014;34(4):158-164
- CountryRepublic of Korea
- Language:English
-
Abstract:
Recently, regenerative medicine utilizing tissue manufacturing has been a creative topic of study, offering promise for resolving the gap between insufficient organ supply and transplantation needs. Moreover, 3D generation of functional organs is seen as the main hope to resolve these issues that will be a major advancement in the field over the next generation. Organ printing is the 3D construction of functional cellular tissue that can replace organs made by additive biofabrication with computational technology. Its advantages offer rapid prototyping (RP) methods for fabricating cells and adjunctive biomaterials layer by layer for manufacturing 3D tissue structures. There is growing interest in applying stem cell research to bio-printing. Recently several bio-printing methods have been developed that accumulate organized 3D structures of living cells by inkjet, extrusion, and laser based printing systems. By printing spatially organized gradients of biomolecules as an extracellular matrix, direct stem cell seeding can then be engineered to differentiate into different lineages forming multiple subpopulations that closely approximate the desired organ. Pliable implementation patches can Stem cells for tissue regeneration can be arranged or deposited onto pliable implementation patches with the purpose of generating functional tissue structures. In this review, current research and advancement of RP-based bio-printing methods to construct synthetic living organs will be discussed. Furthermore, recent accomplishments in bioprinting methods for stem cell study and upcoming endeavors relevant to tissue bioengineering, regenerative medicine and wound healing will be examined.
