Characterisation And Design Of Tissue Scaffolds

Characterisation and Design of Tissue Scaffolds offers scientists a useful guide on the characterization of tissue scaffolds, detailing what needs to be measured and why, how such measurements can be made, and addressing industrially important issues. Part one provides readers with information on the fundamental considerations in the characterization of tissue scaffolds, while other sections detail how to prepare tissue scaffolds, discuss techniques in characterization, and present practical considerations for manufacturers. Summarizes concepts and current practice in the characterization and design of tissue scaffolds Discusses design and preparation of scaffolds Details how to prepare tissue scaffolds, discusses techniques in characterization, and presents practical considerations for manufacturers

In order to enhance the application potential of scaffolds in tissue engineering, comprehensive characterization of scaffold micro- and macro-structure, porosity, permeability and mechanical properties are required. In addition, before in vivo studies can be carried out, a complete assessment of the in vitro behavior of scaffolds, e.g. in selected cell culture studies, is required. The present chapter revises the wide range of methods applied to characterize scaffolds and emphasizes the need for a combination of different characterization techniques for understanding scaffold performance required for successful bone regeneration.

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.

Hydrogels for Tissue Engineering and Regenerative Medicine: From Fundaments to Applications provides the reader with a comprehensive, concise and thoroughly up-to-date resource on the different types of hydrogels in tissue engineering and regenerative medicine. The book is divided into three main sections that describe biological activities and the structural and physicochemical properties of hydrogels, along with a wide range of applications, including their combination with emerging technologies. Written by a diverse range of international academics for professionals, researchers, undergraduate and graduate students, this groundbreaking publication fills a gap in literature needed in the tissue engineering and regenerative medicine field. Reviews the fundamentals and recent advances of hydrogels in tissue engineering and regenerative medicine applications Presents state-of-the-art methodologies for the synthesis and processing of different types of hydrogels Includes contributions by leading experts in engineering, the life sciences, microbiology and clinical medicine

This new volume explores the latest research on the use of alginate as a biopolymer in various biomedical applications and therapeutics. The uses of alginates and modified alginates discussed in this book include tissue regeneration, encapsulation and delivery of drugs, nucleic acid materials, proteins and peptides, genes, herbal therapeutic agents, nutraceuticals, and more. This book also describes the synthesis and characterizations of various alginate and modified alginate systems, such as hydrogels, gels, composites, nanoparticles, scaffolds, etc., used for the biomedical applications and therapeutics. Alginate, a biopolymer of natural origin, is of immense interest for its variety of applications in pharmaceuticals (as medical diagnostic aids) and in materials science. It is the one of the most abundant natural biopolymers and is considered an excellent excipient because of its non-toxic, stable, and biodegradable properties. Several research innovations have been made on applications of alginate in drug delivery and biomedicines. There needs to be a thorough understanding of the synthesis, purification, and characterization of alginates and its derivatives for their utility in healthcare fields, and this volume offers an abundance of information toward that end.

Design, Characterization and Fabrication of Polymer Scaffolds for Tissue Engineering covers core elements of scaffold design, from properties and characterization of polymeric scaffolds to fabrication techniques and the structure-property relationship. Particular attention is given to the cell-scaffold interaction at the molecular level, helping the reader understand and adapt scaffold design to improve biocompatibility and function. The book goes on to discuss a range of tissue engineering applications for polymeric scaffolds, including bone, nerve, cardiac and fibroblast tissue engineering. Design, Characterization and Fabrication of Polymer Scaffolds for Tissue Engineering is an important, interdisciplinary work of relevance to materials scientists, polymer scientists, biomedical engineers and those working regenerative medicine. Helps the reader determine the most appropriate polymer for scaffold design by characterization, properties and structure-property relationship Discusses material-cell interactions at the molecular level, aiding in determining suitability Covers core elements of scaffold design, including fabrication techniques

Nanocomposites for Musculoskeletal Tissue Regeneration discusses the advanced biomaterials scientists are exploring for use as tools to mimic the structure of musculoskeletal tissues. Bone and other musculoskeletal tissues naturally have a nanocomposite structure, therefore nanocomposites are ideally suited as a material for replacing and regenerating these natural tissues. In addition, biological properties such as biointegration and the ability to tailor and dope the materials make them highly desirable for musculoskeletal tissue regeneration. Provides a comprehensive discussion on the design and advancements made in the use of nanocomposites for musculoskeletal tissue regeneration Presents an In-depth coverage of material properties Includes discussions on polymers, ceramics, and glass

This book highlights the latest, cutting-edge advances in implantable biomaterials. It brings together a class of advanced biomaterials in two highly active research areas, namely implants and tissue scaffolds, to underline their respective functional requirements for further development. It is unique in providing a full range of methodological procedures, including materials syntheses, characterisation, cellular tests and mathematical modelling. Covering metallic, ceramic, polymeric and composite materials commonly used in biological applications and clinical therapeutics, it is a valuable resource for anyone wanting to further their understanding of the latest developments in implantable biomaterials. Focusing on biomedical applications in implants and scaffolds, it provides methodological guides to this rapidly growing field. Qing Li and Yiu-Wing Mai are both professors at the University of Sydney, School of Aerospace, Mechanical and Mechatronic Engineering.