Conductive biomaterials for tissue engineering applications

Mani Gajendiran; Jonghoon Choi; Se Jeong Kim; Keongsoo Kim; Heungsoo Shin; Hyung Jun Koo; Kyobum Kim

doi:10.1016/j.jiec.2017.02.031

Conductive biomaterials for tissue engineering applications

Mani Gajendiran, Jonghoon Choi, Se Jeong Kim, Keongsoo Kim, Heungsoo Shin, Hyung Jun Koo, Kyobum Kim

Department of Chemical and Biochemical Engineering

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

106 Scopus citations

Abstract

Conductive biomaterials with a suitable biocompatibility have been utilized to fabricate in vitro platforms for differentiation of progenitor cell population as well as implantable tissue engineering scaffolds. This review evaluates biocompatibility of various conductive biomaterials and relevant fabrication techniques including coating, incorporation into composites, and functionalization with biological moieties. In addition, recent developments in tissue engineering applications using various conductive biomaterials are discussed in detail. Therefore, this overview could provide fundamental knowledge for engineering strategies in regulation of stem cell differentiation, maintenance of phenotypic characteristics, and design of functional implantable scaffolds for better regenerative medicines.

Original language	English
Pages (from-to)	12-26
Number of pages	15
Journal	Journal of Industrial and Engineering Chemistry
Volume	51
DOIs	https://doi.org/10.1016/j.jiec.2017.02.031
State	Published - 25 Jul 2017

Keywords

Biocompatibility
Composite hydrogel
Conductive biomaterials
Fabrication strategies
Tissue engineering

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10.1016/j.jiec.2017.02.031

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title = "Conductive biomaterials for tissue engineering applications",

abstract = "Conductive biomaterials with a suitable biocompatibility have been utilized to fabricate in vitro platforms for differentiation of progenitor cell population as well as implantable tissue engineering scaffolds. This review evaluates biocompatibility of various conductive biomaterials and relevant fabrication techniques including coating, incorporation into composites, and functionalization with biological moieties. In addition, recent developments in tissue engineering applications using various conductive biomaterials are discussed in detail. Therefore, this overview could provide fundamental knowledge for engineering strategies in regulation of stem cell differentiation, maintenance of phenotypic characteristics, and design of functional implantable scaffolds for better regenerative medicines.",

keywords = "Biocompatibility, Composite hydrogel, Conductive biomaterials, Fabrication strategies, Tissue engineering",

author = "Mani Gajendiran and Jonghoon Choi and Kim, {Se Jeong} and Keongsoo Kim and Heungsoo Shin and Koo, {Hyung Jun} and Kyobum Kim",

note = "Publisher Copyright: {\textcopyright} 2017 The Korean Society of Industrial and Engineering Chemistry",

year = "2017",

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doi = "10.1016/j.jiec.2017.02.031",

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T1 - Conductive biomaterials for tissue engineering applications

AU - Gajendiran, Mani

AU - Choi, Jonghoon

AU - Kim, Se Jeong

AU - Kim, Keongsoo

AU - Shin, Heungsoo

AU - Koo, Hyung Jun

AU - Kim, Kyobum

PY - 2017/7/25

Y1 - 2017/7/25

N2 - Conductive biomaterials with a suitable biocompatibility have been utilized to fabricate in vitro platforms for differentiation of progenitor cell population as well as implantable tissue engineering scaffolds. This review evaluates biocompatibility of various conductive biomaterials and relevant fabrication techniques including coating, incorporation into composites, and functionalization with biological moieties. In addition, recent developments in tissue engineering applications using various conductive biomaterials are discussed in detail. Therefore, this overview could provide fundamental knowledge for engineering strategies in regulation of stem cell differentiation, maintenance of phenotypic characteristics, and design of functional implantable scaffolds for better regenerative medicines.

AB - Conductive biomaterials with a suitable biocompatibility have been utilized to fabricate in vitro platforms for differentiation of progenitor cell population as well as implantable tissue engineering scaffolds. This review evaluates biocompatibility of various conductive biomaterials and relevant fabrication techniques including coating, incorporation into composites, and functionalization with biological moieties. In addition, recent developments in tissue engineering applications using various conductive biomaterials are discussed in detail. Therefore, this overview could provide fundamental knowledge for engineering strategies in regulation of stem cell differentiation, maintenance of phenotypic characteristics, and design of functional implantable scaffolds for better regenerative medicines.

KW - Biocompatibility

KW - Composite hydrogel

KW - Conductive biomaterials

KW - Fabrication strategies

KW - Tissue engineering

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DO - 10.1016/j.jiec.2017.02.031

M3 - Review article

AN - SCOPUS:85016805765

SN - 1226-086X

VL - 51

SP - 12

EP - 26

JO - Journal of Industrial and Engineering Chemistry

JF - Journal of Industrial and Engineering Chemistry

ER -

Conductive biomaterials for tissue engineering applications

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Keywords

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