Bioprinting In Regenerative Medicine

This volume presents the current state of laser-assisted bioprinting, a cutting edge tissue engineering technology. Nineteen chapters discuss the most recent developments in using this technology for engineering different types of tissue. Beginning with an overview, the discussion covers bioprinting in cell viability and pattern viability, tissue microfabrication to study cell proliferation, microenvironment for controlling stem cell fate, cell differentiation, zigzag cellular tubes, cartilage tissue engineering, osteogenesis, vessel substitutes, skin tissue and much more. Because bioprinting is on its way to becoming a dominant technology in tissue-engineering, Bioprinting in Regenerative Medicine is essential reading for those researching or working in regenerative medicine, tissue engineering or translational research. Those studying or working with stem cells who are interested in the development of the field will also find the information invaluable.

Regenerative engineering is the convergence of developmental biology, stem cell science and engineering, materials science, and clinical translation to provide tissue patches or constructs for diseased or damaged organs. Various methods have been introduced to create tissue constructs with clinically relevant dimensions. Among such methods, 3D bioprinting provides the versatility, speed and control over location and dimensions of the deposited structures. Three-dimensional bioprinting has leveraged the momentum in printing and tissue engineering technologies and has emerged as a versatile method of fabricating tissue blocks and patches. The flexibility of the system lies in the fact that numerous biomaterials encapsulated with living cells can be printed. This book contains an extensive collection of papers by world-renowned experts in 3D bioprinting. In addition to providing entry-level knowledge about bioprinting, the authors delve into the latest advances in this technology. Furthermore, details are included about the different technologies used in bioprinting. In addition to the equipment for bioprinting, the book also describes the different biomaterials and cells used in these approaches. This text: Presents the principles and applications of bioprinting Discusses bioinks for 3D printing Explores applications of extrusion bioprinting, including past, present, and future challenges Includes discussion on 4D Bioprinting in terms of mechanisms and applications

Three-dimensional (3D) printing enables the fabrication of tissue-engineered constructs and devices from a patient’s own medical data, leading to the creation of anatomically matched and patient-specific constructs. There is a growing interest in applying 3D printing technologies in the fields of tissue engineering and regenerative medicine. The main printing methods include extrusion-based, vat photopolymerization, droplet-based, and powder-based printing. A variety of materials have been used for printing, from metal alloys and ceramics to polymers and elastomers as well as from hydrogels to extracellular matrix proteins. More recently, bioprinting, a subcategory of 3D printing, has enabled the precise assembly of cell-laden biomaterials (i.e., bioinks) for the construction of complex 3D functional living tissues or artificial organs. In this Special Issue, we aim to capture state-of-the-art research papers and the most current review papers focusing on 3D printing for tissue engineering and regenerative medicine. In particular, we seek novel studies on the development of 3D printing and bioprinting approaches, developing printable materials (inks and bioinks), and utilizing 3D-printed scaffolds for tissue engineering and regenerative medicine applications. These applications are not limited to but include scaffolds for in vivo tissue regeneration and tissue analogues for in vitro disease modeling and/or drug screening.

Innovation is added value to a known process. Bioprinting: Techniques and Risks for Regenerative Medicine aims to stimulate a scientifically grounded, interdisciplinary, multiscale debate and exchange of ideas using the techniques described in the book. 3D printing and additive manufacturing evolved from within the field of Cell Biology will have the ability to recreate cells queried from large amounts of phenotypic and molecular data. Stem Cell biologists, biotechnologists and material engineers, as well as graduate students will greatly benefit from the practical knowledge and case examples provided throughout this book. Shows the possible risk of rejection of 3D printed cells. Contains bioprinting techniques in literature plus actual 3D files adapted and created by the author using several types of 3d printers Provides information on how to convert an existing 3-D printer to bioprinter using currently available techniques Describes the increased complexity of bioprinting compared to 3D- printing Discussion on how 3D printing and additive manufacturing offers the opportunity to 3D print an entire organ, reducing the associated costs of this process when using cells as bioink

This volume explores laser-assisted bioprinting, focusing on the most recent developments in its use for tissue engineering. Bringing together authoritative and international perspectives, the text begins with an overview and goes on to cover bioprinting in cell viability and pattern viability, tissue microfabrication to study cell proliferation, microenvironment for controlling stem cell fate, cell differentiation, zigzag cellular tubes, cartilage tissue engineering, osteogenesis, vessel substitutes, skin tissue and much more. Bioprinting is on its way to becoming a dominant technology in tissue-engineering; Bioprinting in Regenerative Medicine, from the bestselling Stem Cell Biology in Regenerative Medicine series, is essential reading for those researching or working in regenerative medicine, tissue engineering, or translational research. Those studying or working with stem cells who are interested in the development of the field will also find the information invaluable.

3D Bioprinting and Nanotechnology in Tissue Engineering and Regenerative Medicine, Second Edition provides an in-depth introduction to bioprinting and nanotechnology and their industrial applications. Sections cover 4D Printing Smart Multi-responsive Structure, Cells for Bioprinting, 4D Printing Biomaterials, 3D/4D printing functional biomedical devices, 3D Printing for Cardiac and Heart Regeneration, Integrating 3D printing with Ultrasound for Musculoskeletal Regeneration, 3D Printing for Liver Regeneration, 3D Printing for Cancer Studies, 4D Printing Soft Bio-robots, Clinical Translation and Future Directions. The book's team of expert contributors have pooled their expertise in order to provide a summary of the suitability, sustainability and limitations of each technique for each specific application. The increasing availability and decreasing costs of nanotechnologies and 3D printing technologies are driving their use to meet medical needs. This book provides an overview of these technologies and their integration. Includes clinical applications, regulatory hurdles, and a risk-benefit analysis of each technology Assists readers in selecting the best materials and how to identify the right parameters for printing Includes the advantages of integrating 3D printing and nanotechnology in order to improve the safety of nano-scale materials for biomedical applications

This book is the first of two volumes that together offer a comprehensive account of cutting-edge advances in the development of biomaterials for use within tissue engineering and regenerative medicine. Topics addressed in this volume, which is devoted to bioinspired biomaterials, range from novel biomaterials for regenerative medicine through to emerging enabling technologies with applications in, for example, drug delivery, maternal–fetal medicine, peripheral nerve repair and regeneration, and brain tumor therapy. New bioinspired hydrogels receive detailed attention in the book, and a further focus is the use of bioinspired biomaterials in the regulation of stem cell fate. Here the coverage includes the role of scaffolds in cartilage regeneration, the bioapplication of inorganic nanomaterials in tissue engineering, and guidance of cell migration to improve tissue regeneration. The authors are recognized experts in the interdisciplinary field of regenerative medicine and the book will be of value for all with an interest in regenerative medicine based on biomaterials.

3D Bioprinting for Reconstructive Surgery: Techniques and Applications examines the combined use of materials, procedures and tools necessary for creating structural tissue constructs for reconstructive purposes. Offering a broad analysis of the field, the first set of chapters review the range of biomaterials which can be used to create 3D-printed tissue constructs. Part Two looks at the techniques needed to prepare biomaterials and biological materials for 3D printing, while the final set of chapters examines application-specific examples of tissues formed from 3D printed biomaterials. 3D printing of biomaterials for tissue engineering applications is becoming increasingly popular due to its ability to offer unique, patient-specific parts—on demand—at a relatively low cost. This book is a valuable resource for biomaterials scientists, biomedical engineers, practitioners and students wishing to broaden their knowledge in the allied field. Discusses new possibilities in tissue engineering with 3D printing Presents a comprehensive coverage of the materials, techniques and tools needed for producing bioprinted tissues Reviews emerging technologies in addition to commercial techniques