3D bioprinting and its in vivo applications

Nhayoung Hong; Gi Hoon Yang; Jae Hwan Lee; Geun Hyung Kim

doi:10.1002/jbm.b.33826

3D bioprinting and its in vivo applications

Nhayoung Hong
, Gi Hoon Yang
, Jae Hwan Lee
, Geun Hyung Kim

Sungkyunkwan University

Research output: Contribution to journal › Review article › peer-review

210 Scopus citations

Abstract

The purpose of 3D bioprinting technology is to design and create functional 3D tissues or organs in situ for in vivo applications. 3D cell-printing, or additive biomanufacturing, allows the selection of biomaterials and cells (bioink), and the fabrication of cell-laden structures in high resolution. 3D cell-printed structures have also been used for applications such as research models, drug delivery and discovery, and toxicology. Recently, numerous attempts have been made to fabricate tissues and organs by using various 3D printing techniques. However, challenges such as vascularization are yet to be solved. This article reviews the most commonly used 3D cell-printing techniques with their advantages and drawbacks. Furthermore, up-to-date achievements of 3D bioprinting in in vivo applications are introduced, and prospects for the future of 3D cell-printing technology are discussed.

Original language	English
Pages (from-to)	444-459
Number of pages	16
Journal	Journal of Biomedical Materials Research - Part B Applied Biomaterials
Volume	106
Issue number	1
DOIs	https://doi.org/10.1002/jbm.b.33826
State	Published - Jan 2018

Keywords

3D bioprinting
clinical application
tissue engineering

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10.1002/jbm.b.33826

Cite this

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title = "3D bioprinting and its in vivo applications",

abstract = "The purpose of 3D bioprinting technology is to design and create functional 3D tissues or organs in situ for in vivo applications. 3D cell-printing, or additive biomanufacturing, allows the selection of biomaterials and cells (bioink), and the fabrication of cell-laden structures in high resolution. 3D cell-printed structures have also been used for applications such as research models, drug delivery and discovery, and toxicology. Recently, numerous attempts have been made to fabricate tissues and organs by using various 3D printing techniques. However, challenges such as vascularization are yet to be solved. This article reviews the most commonly used 3D cell-printing techniques with their advantages and drawbacks. Furthermore, up-to-date achievements of 3D bioprinting in in vivo applications are introduced, and prospects for the future of 3D cell-printing technology are discussed.",

keywords = "3D bioprinting, clinical application, tissue engineering",

author = "Nhayoung Hong and Yang, \{Gi Hoon\} and Lee, \{Jae Hwan\} and Kim, \{Geun Hyung\}",

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year = "2018",

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doi = "10.1002/jbm.b.33826",

language = "English",

volume = "106",

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AU - Hong, Nhayoung

AU - Yang, Gi Hoon

AU - Lee, Jae Hwan

AU - Kim, Geun Hyung

PY - 2018/1

Y1 - 2018/1

N2 - The purpose of 3D bioprinting technology is to design and create functional 3D tissues or organs in situ for in vivo applications. 3D cell-printing, or additive biomanufacturing, allows the selection of biomaterials and cells (bioink), and the fabrication of cell-laden structures in high resolution. 3D cell-printed structures have also been used for applications such as research models, drug delivery and discovery, and toxicology. Recently, numerous attempts have been made to fabricate tissues and organs by using various 3D printing techniques. However, challenges such as vascularization are yet to be solved. This article reviews the most commonly used 3D cell-printing techniques with their advantages and drawbacks. Furthermore, up-to-date achievements of 3D bioprinting in in vivo applications are introduced, and prospects for the future of 3D cell-printing technology are discussed.

AB - The purpose of 3D bioprinting technology is to design and create functional 3D tissues or organs in situ for in vivo applications. 3D cell-printing, or additive biomanufacturing, allows the selection of biomaterials and cells (bioink), and the fabrication of cell-laden structures in high resolution. 3D cell-printed structures have also been used for applications such as research models, drug delivery and discovery, and toxicology. Recently, numerous attempts have been made to fabricate tissues and organs by using various 3D printing techniques. However, challenges such as vascularization are yet to be solved. This article reviews the most commonly used 3D cell-printing techniques with their advantages and drawbacks. Furthermore, up-to-date achievements of 3D bioprinting in in vivo applications are introduced, and prospects for the future of 3D cell-printing technology are discussed.

KW - 3D bioprinting

KW - clinical application

KW - tissue engineering

UR - https://www.scopus.com/pages/publications/85010815459

U2 - 10.1002/jbm.b.33826

DO - 10.1002/jbm.b.33826

M3 - Review article

C2 - 28106947

AN - SCOPUS:85010815459

SN - 1552-4973

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JO - Journal of Biomedical Materials Research - Part B Applied Biomaterials

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ER -

3D bioprinting and its in vivo applications

Abstract

Keywords

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