25th Anniversary Article: Engineering Hydrogels for Biofabrication

Jos Malda; Jetze Visser; Ferry P. Melchels; Tomasz Juengst; Wim E. Hennink; Wouter J. A. Dhert; Juergen Groll; Dietmar W. Hutmacher

doi:10.1002/adma.201302042

25th Anniversary Article: Engineering Hydrogels for Biofabrication

Jos Malda^*, Jetze Visser, Ferry P. Melchels, Tomasz Juengst, Wim E. Hennink, Wouter J. A. Dhert, Juergen Groll, Dietmar W. Hutmacher

^*Corresponding author for this work

Pharmaceutics

Research output: Contribution to journal › Literature review › peer-review

Abstract

With advances in tissue engineering, the possibility of regenerating injured tissue or failing organs has become a realistic prospect for the first time in medical history. Tissue engineering - the combination of bioactive materials with cells to generate engineered constructs that functionally replace lost and/or damaged tissue - is a major strategy to achieve this goal. One facet of tissue engineering is biofabrication, where three-dimensional tissue-like structures composed of biomaterials and cells in a single manufacturing procedure are generated. Cell-laden hydrogels are commonly used in biofabrication and are termed bioinks. Hydrogels are particularly attractive for biofabrication as they recapitulate several features of the natural extracellular matrix and allow cell encapsulation in a highly hydrated mechanically supportive three-dimensional environment. Additionally, they allow for efficient and homogeneous cell seeding, can provide biologically-relevant chemical and physical signals, and can be formed in various shapes and biomechanical characteristics. However, despite the progress made in modifying hydrogels for enhanced bioactivation, cell survival and tissue formation, little attention has so far been paid to optimize hydrogels for the physico-chemical demands of the biofabrication process. The resulting lack of hydrogel bioinks have been identified as one major hurdle for a more rapid progress of the field. In this review we summarize and focus on the deposition process, the parameters and demands of hydrogels in biofabrication, with special attention to robotic dispensing as an approach that generates constructs of clinically relevant dimensions. We aim to highlight this current lack of effectual hydrogels within biofabrication and initiate new ideas and developments in the design and tailoring of hydrogels. The successful development of a printable hydrogel that supports cell adhesion, migration, and differentiation will significantly advance this exciting and promising approach for tissue engineering.

Original language	English
Pages (from-to)	5011-5028
Number of pages	18
Journal	Advanced Materials
Volume	25
Issue number	36
DOIs	https://doi.org/10.1002/adma.201302042
Publication status	Published - Sept 2013

Funding

This article is part of an ongoing series celebrating the 25th anniversary of Advanced Materials. We extend our thanks to Dr. Paul Dalton for proof reading the manuscript. The research leading to these results has received funding from the European Community's Seventh Framework Programme (FP7/2007-2013) under grant agreements no 309962 (HydroZONES) and no 272286 (PrintCART). Jetze Visser was supported by a grant from the Dutch government to the Netherlands Institute for Regenerative Medicine (NIRM, grant no FES0908), Jos Malda was supported by the Dutch Arthritis Foundation and Dietmar W Hutmacher by the Hans Fischer Senior Fellowship, Institute for Advanced Studies, Technical University Munich.

Keywords

bioprinting
biofabrication
additive manufacturing
hydrogel
biomaterials
biopolymers
DOUBLE-NETWORK HYDROGELS
3-DIMENSIONAL FREEFORM FABRICATION
CELL-LADEN
ENDOTHELIAL-CELLS
CARTILAGE REPAIR
CROSS-LINKING
BIOMEDICAL APPLICATIONS
EXTRACELLULAR MATRICES
PRINTING APPLICATIONS
TRIBLOCK COPOLYMERS

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10.1002/adma.201302042

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@article{db0432fdd28f4bac8f5c826cc8ddd8f6,

title = "25th Anniversary Article: Engineering Hydrogels for Biofabrication",

abstract = "With advances in tissue engineering, the possibility of regenerating injured tissue or failing organs has become a realistic prospect for the first time in medical history. Tissue engineering - the combination of bioactive materials with cells to generate engineered constructs that functionally replace lost and/or damaged tissue - is a major strategy to achieve this goal. One facet of tissue engineering is biofabrication, where three-dimensional tissue-like structures composed of biomaterials and cells in a single manufacturing procedure are generated. Cell-laden hydrogels are commonly used in biofabrication and are termed bioinks. Hydrogels are particularly attractive for biofabrication as they recapitulate several features of the natural extracellular matrix and allow cell encapsulation in a highly hydrated mechanically supportive three-dimensional environment. Additionally, they allow for efficient and homogeneous cell seeding, can provide biologically-relevant chemical and physical signals, and can be formed in various shapes and biomechanical characteristics. However, despite the progress made in modifying hydrogels for enhanced bioactivation, cell survival and tissue formation, little attention has so far been paid to optimize hydrogels for the physico-chemical demands of the biofabrication process. The resulting lack of hydrogel bioinks have been identified as one major hurdle for a more rapid progress of the field. In this review we summarize and focus on the deposition process, the parameters and demands of hydrogels in biofabrication, with special attention to robotic dispensing as an approach that generates constructs of clinically relevant dimensions. We aim to highlight this current lack of effectual hydrogels within biofabrication and initiate new ideas and developments in the design and tailoring of hydrogels. The successful development of a printable hydrogel that supports cell adhesion, migration, and differentiation will significantly advance this exciting and promising approach for tissue engineering.",

keywords = "bioprinting, biofabrication, additive manufacturing, hydrogel, biomaterials, biopolymers, DOUBLE-NETWORK HYDROGELS, 3-DIMENSIONAL FREEFORM FABRICATION, CELL-LADEN, ENDOTHELIAL-CELLS, CARTILAGE REPAIR, CROSS-LINKING, BIOMEDICAL APPLICATIONS, EXTRACELLULAR MATRICES, PRINTING APPLICATIONS, TRIBLOCK COPOLYMERS",

author = "Jos Malda and Jetze Visser and Melchels, {Ferry P.} and Tomasz Juengst and Hennink, {Wim E.} and Dhert, {Wouter J. A.} and Juergen Groll and Hutmacher, {Dietmar W.}",

year = "2013",

month = sep,

doi = "10.1002/adma.201302042",

language = "English",

volume = "25",

pages = "5011--5028",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley-Blackwell",

number = "36",

}

TY - JOUR

T1 - 25th Anniversary Article

T2 - Engineering Hydrogels for Biofabrication

AU - Malda, Jos

AU - Visser, Jetze

AU - Melchels, Ferry P.

AU - Juengst, Tomasz

AU - Hennink, Wim E.

AU - Dhert, Wouter J. A.

AU - Groll, Juergen

AU - Hutmacher, Dietmar W.

PY - 2013/9

Y1 - 2013/9

N2 - With advances in tissue engineering, the possibility of regenerating injured tissue or failing organs has become a realistic prospect for the first time in medical history. Tissue engineering - the combination of bioactive materials with cells to generate engineered constructs that functionally replace lost and/or damaged tissue - is a major strategy to achieve this goal. One facet of tissue engineering is biofabrication, where three-dimensional tissue-like structures composed of biomaterials and cells in a single manufacturing procedure are generated. Cell-laden hydrogels are commonly used in biofabrication and are termed bioinks. Hydrogels are particularly attractive for biofabrication as they recapitulate several features of the natural extracellular matrix and allow cell encapsulation in a highly hydrated mechanically supportive three-dimensional environment. Additionally, they allow for efficient and homogeneous cell seeding, can provide biologically-relevant chemical and physical signals, and can be formed in various shapes and biomechanical characteristics. However, despite the progress made in modifying hydrogels for enhanced bioactivation, cell survival and tissue formation, little attention has so far been paid to optimize hydrogels for the physico-chemical demands of the biofabrication process. The resulting lack of hydrogel bioinks have been identified as one major hurdle for a more rapid progress of the field. In this review we summarize and focus on the deposition process, the parameters and demands of hydrogels in biofabrication, with special attention to robotic dispensing as an approach that generates constructs of clinically relevant dimensions. We aim to highlight this current lack of effectual hydrogels within biofabrication and initiate new ideas and developments in the design and tailoring of hydrogels. The successful development of a printable hydrogel that supports cell adhesion, migration, and differentiation will significantly advance this exciting and promising approach for tissue engineering.

AB - With advances in tissue engineering, the possibility of regenerating injured tissue or failing organs has become a realistic prospect for the first time in medical history. Tissue engineering - the combination of bioactive materials with cells to generate engineered constructs that functionally replace lost and/or damaged tissue - is a major strategy to achieve this goal. One facet of tissue engineering is biofabrication, where three-dimensional tissue-like structures composed of biomaterials and cells in a single manufacturing procedure are generated. Cell-laden hydrogels are commonly used in biofabrication and are termed bioinks. Hydrogels are particularly attractive for biofabrication as they recapitulate several features of the natural extracellular matrix and allow cell encapsulation in a highly hydrated mechanically supportive three-dimensional environment. Additionally, they allow for efficient and homogeneous cell seeding, can provide biologically-relevant chemical and physical signals, and can be formed in various shapes and biomechanical characteristics. However, despite the progress made in modifying hydrogels for enhanced bioactivation, cell survival and tissue formation, little attention has so far been paid to optimize hydrogels for the physico-chemical demands of the biofabrication process. The resulting lack of hydrogel bioinks have been identified as one major hurdle for a more rapid progress of the field. In this review we summarize and focus on the deposition process, the parameters and demands of hydrogels in biofabrication, with special attention to robotic dispensing as an approach that generates constructs of clinically relevant dimensions. We aim to highlight this current lack of effectual hydrogels within biofabrication and initiate new ideas and developments in the design and tailoring of hydrogels. The successful development of a printable hydrogel that supports cell adhesion, migration, and differentiation will significantly advance this exciting and promising approach for tissue engineering.

KW - bioprinting

KW - biofabrication

KW - additive manufacturing

KW - hydrogel

KW - biomaterials

KW - biopolymers

KW - DOUBLE-NETWORK HYDROGELS

KW - 3-DIMENSIONAL FREEFORM FABRICATION

KW - CELL-LADEN

KW - ENDOTHELIAL-CELLS

KW - CARTILAGE REPAIR

KW - CROSS-LINKING

KW - BIOMEDICAL APPLICATIONS

KW - EXTRACELLULAR MATRICES

KW - PRINTING APPLICATIONS

KW - TRIBLOCK COPOLYMERS

U2 - 10.1002/adma.201302042

DO - 10.1002/adma.201302042

M3 - Literature review

SN - 0935-9648

VL - 25

SP - 5011

EP - 5028

JO - Advanced Materials

JF - Advanced Materials

IS - 36

ER -

25th Anniversary Article: Engineering Hydrogels for Biofabrication

Abstract

Funding

Keywords

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