Download Free Nanostructured Biomaterials For Regenerative Medicine Book in PDF and EPUB Free Download. You can read online Nanostructured Biomaterials For Regenerative Medicine and write the review.

Nanostructured Biomaterials for Regenerative Medicine focuses on the definition of new trends for the design of biomaterials for biomedical applications. It includes the ex novo synthesis as well as technological strategies to manipulate them into appropriate two-dimensional (2D) and three-dimensional (3D) forms, in order to impart all the main physical, chemical, structural and biological properties requested to achieve desired clinical efficacy. This book aims at offering a concise overview of innovative platforms based on nanostructured biomaterials as a function of their chemical nature - established by a consolidated material classification i.e., polymer, ceramics and metals. For each class, emerging bioinspired systems with rapid expansion in the biomedical research area and fabricated via new enabling technologies will be proposed for the use in tissue repair/regeneration and nanomedicine. This book is an essential resource for researchers, academics and professionals interested in the potential of nanostructured biomaterials for regenerative medicine. Classifies materials into three classes for comprehensive discussion Discusses design techniques to create innovative nanostructured biomaterials Looks at enabling technologies and strategies for emerging applications
Although nanotechnology applied to medicine has a potentially huge impact on drug delivery and tissue engineering, significant challenges need to be resolved before clinically viable nanomedicine or nanobiomedicine therapies will be available. Skillfully edited, with contributions from an expert panel of researchers, Nanotechnology in Tissue Engine
New Trends in Smart Nanostructured Biomaterials in Health Sciences provides guidance on the design and synthesis of nanostructured smart biomaterials, as well as the resultant therapeutic effects and associated biomedical applications of these novel materials. The book provides readers with a deeper understanding of these novel biomaterials and aids them in making informed decisions when selecting appropriate materials for tissue engineering and cancer therapy applications. It will be of specific interest to materials scientists, biomedical engineers, oncological scientists, tissue engineers and those working in regenerative medicine. Nanostructured smart materials have the special ability to respond to changes in the cell microenvironment, allowing for robust, biocompatible and rapidly adaptable, therapeutic and restorative action against a range of ailments. These materials are thus ideal candidates for use in tissue engineering and cancer therapy due to the varying nature of the cell microenvironment between persons, tissues and cancers. This book covers the design, synthesis, unique properties and application of smart biomaterials in these two key topic areas of tissue engineering and cancer therapeutics. Presents an overview of how smart biomaterials respond to changes in physiological factors and exogeneous stimuli and their impact in modern medicine Provides readers with the basis for designing, processing and characterizing advanced smart biomaterials Guides the reader through the mechanisms of tissue repair and cancer therapeutics by exploring the most relevant features of smart nanostructured materials
Nanoengineered Biomaterials for Regenerative Medicine showcases the advances that have taken place in recent years as an increasing number of nanoengineered biomaterials have been targeted to various organ tissues. The book systematically explores how nanoengineered biomaterials are used in different aspects of regenerative medicine, including bone regeneration, brain tissue reconstruction and kidney repair. It is a valuable reference resource for scientists working in biomaterials science who want to learn more about how nanoengineered materials are practically applied in regenerative medicine. Nanoengineered biomaterials have gained particular focus due to their many advantages over conventional techniques for tissue repair. As a wide range of biomaterials and nanotechnology techniques have been examined for the regeneration of tissues, this book highlights the discussions and advancements made. Provides a digestible reference source for surgeons and physicians who want to learn more on nanoengineered biomaterials and their use in effective medical treatments Offers systematic coverage on how nanoengineered biomaterials are used for different types of medicine Assesses the benefits and drawbacks of the use of bioengineered nanomaterials in different areas of regenerative medicine
- The first reference work ever published on nanostructured biomaterials and their applications. - A unique source of in-depth knowledge of recent advances in applications of nanostructured biomaterials. Most up-to-date emerging aspects of nanobiomaterials and their applications in the field of nanotechnology. - Contains 33 state-of-the-art chapters written by over 70 internationally renowned experts from 10 countries. - About 5,000 bibliographic citations and hundreds of illustrations, figures, tables, chemical structures and equations.
Nanostructured Materials for Tissue Engineering introduces the key properties and approaches involved in using nanostructured materials in tissue engineering, including functionalization, nanotechnology-based regenerative techniques, toxicological and biocompatible aspects. A broad range of nanomaterial types are covered, from polymer scaffolds and nanocomposites to gold nanoparticles and quantum dots. This book aids the reader in materials selection, as well as matching to the best applications, including bone, skin, pulmonary or neurological tissue engineering. Users will find this book to be an up-to-date review on this fast-changing field that is ideal for materials scientists, tissue engineers, biomedical engineers, and pharmaceutical scientists. Covers the most recent advances in this fast-moving field, including all key aspects from properties and functionalization to materials selection and application in tissue engineering Reviews a variety of nanomaterials and their benefits, including polymeric, gold and carbon nanoparticles Explores a range of tissue engineering applications, such as cardiovascular therapies, skin repair and regeneration, and diabetes management
Nanostructured materials have been explored in biomedical field especially in tissue engineering over a past decade. This type of material can be processed into biomaterial scaffolds; revealed many advantages to be used in human living system such as restoring, healing, replacing and improving the function of interested tissues or organs. In this work, nanostructured materials were synthesized as a nanofibrous scaffold or nanoparticles, which were characterized and tested for their biofunctions in the regeneration of blood vessels, lung and skin tissues. Firstly, biodegradable polyurethane nanofibrous scaffolds with dipyramole were electrospun to create a vascular graft, and results demonstrated that this nanofibrous scaffold matched the native artery mechanical strength, reduced the platelet deposition, improved blood compatibility, supported endothelial cell formation and inhibited the proliferation of smooth muscle cells. Next, biodegradable polylactic-glycolic acid nanoparticles were fabricated and then coated with porcine lung extracellular matrix to maximize the nanoparticle deposition on the alveolar epithelial cells. These nanoparticles also show that they were cytocompatible with alveolar type I epithelial cells and facilitated the cellular retention/uptake. Preliminary studies of electrospun nanofibrous polyurethane scaffold incorporated with nanoparticles loaded with anti-microbial peptide and/or antibiotics for wound healing application demonstrated these nanostructured materials could be used to prevent bacterial infection and suggest their potential in skin wound healing applications. Results from this research suggest that the biomaterials either in the nanofiber or nanoparticle structures could be used for regeneration of various tissue organs such as blood vessels and skins, and for protein (growth factors) or gene therapy (cDNA plasmids) delivery to facilitate lung regeneration. Hence, the nanostructured biomaterials would have high potential to be applied for tissue regeneration to manage diseased and damaged tissues/organs for human healthcare.
This book provides an overview of the advances on nanostructured celullose from different obtaining forms: natural plants and bacterial microorganisms. It gives the reader an introduction of cellulose focusing in nanosize particles, its potential applications and future perspectives. The potential use of cellulose in the biomedical field is highlighted.
This book fills the gap between fundamental and applied research in the use of nanomaterials in biomedical applications, covering the most relevant areas, such as the fundamental concepts of the preparation of nanostructures and regulatory requirements for their safe use in biomedical devices. It also critically discusses what has been achieved in the field, and what needs to be urgently addressed and reviews the state-of-the-art medical uses of nanomaterials for treating damaged organs and tissues. Combining the expertise of clinical researchers working in the field of tissue engineering and novel materials, the book explores the main topics regarding the characterization of materials, specific organ-oriented biomaterials and their applications, as well as regulations and safety. Further, it also examines recent advances, difficulties, and clinical requirements in terms of human bone, cornea, heart, skin and the nervous system, allowing readers to gain a clear and comprehensive understanding of current nanomaterial use in biomedical applications and devices, together with the challenges and future trends. This book is a valuable tool for multidisciplinary scientists and experts interested in fundamental concepts and synthetic routes for preparing nanomaterials. It is also of interest to students and researchers involved in cross-disciplinary research in nanomaterials for clinical applications and offers practical insights for clinicians as well as engineers and materials scientists working in nanoengineering.