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Table of Contents
Intro
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Since the publication of our first edition, the interest in the field of organ printing has significantly expanded. Organ printing, which uses three-dimensional (3D) printing approaches, offers intriguing opportunities for creating complex 3D biological structures. As an unrivaled multidisciplinary technology, 3D bioprinting can facilitate innovative advances in tissue engineering and regenerative medicine. In particular, 3D bioprinting has emerged as a vital too
Acknowledgements
Author biographies
Jinah Jang
Suhun Chae
Jungbin Yoon
Hyeonji Kim
Wonbin Park
Contributors
Chapter Introduction
References
Chapter Three-dimensional (3D) bioprinting techniques
2.1 Practical workflow to implement bioprinting
2.2 Prevailing 3D bioprinting techniques
2.2.1 Inkjet-based 3D bioprinting technique
2.2.2 Extrusion-based 3D bioprinting technique
2.2.3 Light-based 3D bioprinting technique
2.3 Advanced 3D bioprinting techniques
2.4 Conclusion
2.5 End-of chapter problem and examples
References
Chapter Cell sources
3.1 Primary cells
3.2 Stem cells
3.3 Preparation of cells for 3D organ bioprinting
3.4 Cell spheroids
3.5 Organoids
3.6 End-of chapter problem and examples
References
Chapter Biomaterials
4.1 Synthetic polymers
4.1.1 Polycaprolactone
4.1.2 Polylactic-co-glycolic acid
4.1.3 Pluronic acid
4.1.4 Polydimethylsiloxane
4.1.5 Poly(ethylene glycol)
4.1.6 Polyvinyl alcohol
4.2 Bioinks
4.2.1 Alginate
4.2.2 Collagen
4.2.3 Gelatin
4.2.4 Cellulose
4.2.5 Silk fibroin
4.2.6 Extracellular matrix-based materials
4.3 End-of chapter problem and examples
References
Chapter Three-dimensional (3D) bioprinting application for tissue engineering.
5.1 3D bioprinted orthopedic tissue engineering
5.2 3D bioprinted cardiac tissue engineering
5.3 3D bioprinted vascular tissue engineering
5.3.1 Structural, compositional, and mechanical features of blood vessels
5.3.2 3D bioprinting of vascular graft for vascular tissue regeneration
5.4 3D bioprinted superficial tissue engineering
5.5 End-of chapter problem and examples
References
Chapter Three-dimensional bioprinting application for in vitro tissue/organ models
6.1 3D bioprinting of in vitro intestine (gut) models
6.2 3D bioprinting of in vitro kidney models
6.3 3D bioprinting of in vitro skin and adipose tissue models
6.4 Three-dimensional bioprinting of in vitro blood vessel models
6.5 End-of chapter problem and examples
References
Chapter Future perspective and conclusion
References.
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Since the publication of our first edition, the interest in the field of organ printing has significantly expanded. Organ printing, which uses three-dimensional (3D) printing approaches, offers intriguing opportunities for creating complex 3D biological structures. As an unrivaled multidisciplinary technology, 3D bioprinting can facilitate innovative advances in tissue engineering and regenerative medicine. In particular, 3D bioprinting has emerged as a vital too
Acknowledgements
Author biographies
Jinah Jang
Suhun Chae
Jungbin Yoon
Hyeonji Kim
Wonbin Park
Contributors
Chapter Introduction
References
Chapter Three-dimensional (3D) bioprinting techniques
2.1 Practical workflow to implement bioprinting
2.2 Prevailing 3D bioprinting techniques
2.2.1 Inkjet-based 3D bioprinting technique
2.2.2 Extrusion-based 3D bioprinting technique
2.2.3 Light-based 3D bioprinting technique
2.3 Advanced 3D bioprinting techniques
2.4 Conclusion
2.5 End-of chapter problem and examples
References
Chapter Cell sources
3.1 Primary cells
3.2 Stem cells
3.3 Preparation of cells for 3D organ bioprinting
3.4 Cell spheroids
3.5 Organoids
3.6 End-of chapter problem and examples
References
Chapter Biomaterials
4.1 Synthetic polymers
4.1.1 Polycaprolactone
4.1.2 Polylactic-co-glycolic acid
4.1.3 Pluronic acid
4.1.4 Polydimethylsiloxane
4.1.5 Poly(ethylene glycol)
4.1.6 Polyvinyl alcohol
4.2 Bioinks
4.2.1 Alginate
4.2.2 Collagen
4.2.3 Gelatin
4.2.4 Cellulose
4.2.5 Silk fibroin
4.2.6 Extracellular matrix-based materials
4.3 End-of chapter problem and examples
References
Chapter Three-dimensional (3D) bioprinting application for tissue engineering.
5.1 3D bioprinted orthopedic tissue engineering
5.2 3D bioprinted cardiac tissue engineering
5.3 3D bioprinted vascular tissue engineering
5.3.1 Structural, compositional, and mechanical features of blood vessels
5.3.2 3D bioprinting of vascular graft for vascular tissue regeneration
5.4 3D bioprinted superficial tissue engineering
5.5 End-of chapter problem and examples
References
Chapter Three-dimensional bioprinting application for in vitro tissue/organ models
6.1 3D bioprinting of in vitro intestine (gut) models
6.2 3D bioprinting of in vitro kidney models
6.3 3D bioprinting of in vitro skin and adipose tissue models
6.4 Three-dimensional bioprinting of in vitro blood vessel models
6.5 End-of chapter problem and examples
References
Chapter Future perspective and conclusion
References.