3D Bioprinting: Fundamentals, Principles and Applications3D Bioprinting: Fundamentals, Principles and Applications provides the latest information on the fundamentals, principles, physics, and applications of 3D bioprinting. It contains descriptions of the various bioprinting processes and technologies used in additive biomanufacturing of tissue constructs, tissues, and organs using living cells. The increasing availability and decreasing costs of 3D printing technologies are driving its use to meet medical needs, and this book provides an overview of these technologies and their integration. Each chapter discusses current limitations on the relevant technology, giving future perspectives. Professor Ozbolat has pulled together expertise from the fields of bioprinting, tissue engineering, tissue fabrication, and 3D printing in his inclusive table of contents. Topics covered include raw materials, processes, machine technology, products, applications, and limitations. The information in this book will help bioengineers, tissue and manufacturing engineers, and medical doctors understand the features of each bioprinting process, as well as bioink and bioprinter types. In addition, the book presents tactics that can be used to select the appropriate process for a given application, such as tissue engineering and regenerative medicine, transplantation, clinics, or pharmaceutics. - Describes all aspects of the bioprinting process, from bioink processing through design for bioprinting, bioprinting techniques, bioprinter technologies, organ printing, applications, and future trends - Provides a detailed description of each bioprinting technique with an in-depth understanding of its process modeling, underlying physics and characteristics, suitable bioink and cell types printed, and major accomplishments achieved thus far - Explains organ printing technology in detail with a step-by-step roadmap for the 3D bioprinting of organs from isolating stem cells to the post-transplantation of organs - Presents tactics that can be used to select the appropriate process for a given application, such as tissue engineering and regenerative medicine, transplantation, clinics, or pharmaceutics |
Contents
| 41 | |
4 ExtrusionBased Bioprinting | 93 |
| 125 | |
6 LaserBased Bioprinting | 165 |
7 Bioprinter Technologies | 199 |
8 Roadmap to Organ Printing | 243 |
| 271 | |
10 Future Trends | 313 |
| 337 | |
Back Cover | 343 |
Common terms and phrases
3D bioprinting 3D printing agarose alginate Biofabrication bioink materials bioink solution biological Biomaterials bioprinted tissue bioprinting modalities bioprinting process bioprinting technology bioreactor Biotechnology bone cancer cartilage cell aggregates cell types cell viability cell-laden cellular chitosan chondrocytes collagen commercially available crosslinking demonstrated deposition differentiation droplet droplet-based bioprinting drug electrohydrodynamic encapsulated endothelial cells extrusion extrusion-based bioprinting fibrin fibroblasts functional gelatin gelation high-throughput human hyaluronic acid hydrogels imaging inkjet bioprinting inkjet printing Journal laser laser-based bioprinting layer limited living cells matrix mesenchymal stem cells microcarriers microextrusion nozzle organ printing Ozbolat perfusion photoinitiators piezoelectric Pluronic polymer printer printhead proteins regenerative medicine Reproduced/adapted with permission resolution scaffold-free scaffolds Skardal sodium alginate stem cells stereolithography structures substrate techniques thermal three-dimensional tissue constructs tissue engineering tissue models tissue scaffolds tissue spheroids tissue strands tissues and organs toolpath planning transplantation vascular network vitro vivo Zhang