Download Free Functional Biomaterials Design Synthesis And Applications Book in PDF and EPUB Free Download. You can read online Functional Biomaterials Design Synthesis And Applications and write the review.

Early diagnosis of cancer is still a major challenge in cancer therapy. In recent years, the development of multifunctional nanomaterials has provided a new diagnosis and treatment platform to combat cancer. Polymer-inorganic nanomaterials with novel structures such as bowl-shaped/Janus/core-shell have drawn much attention owing to their diversity in composition or asymmetry in structure. More importantly, imparting unique optical, electrical, and magnetic properties to these nanocomposites can further extend their function repertoire. However, to fulfill this vision, fundamental understandings regarding strategies of precise synthesis, mechanisms of structure formation, in vivo synergistic effects in bioapplications, and biosafety of these materials are needed. Besides, nanomaterials with novel structures are well positioned for imaging-guided cancer theranostic. On one hand, nanomaterials themselves are suitable for imaging because of their intrinsic properties such as fluorescent or magnetic properties. On the other hand, nanomaterials can serve as functional platforms that integrate various therapeutic modalities including photothermal therapy, chemodynamic/ion-interference therapy, photodynamic therapy, and cuproptosis to efficiently kill cancer cells. This Research Topic aims at collecting works about synthesis, and biomedical applications of polymer/mesoporous inorganic nanomaterials, especially in the aspect of novel synthetic approaches for fabricating nanomaterials with unique structures. Additionally, we hope that in-depth research articles on this topic can provide insights into the mechanism of nanomaterials acting in cancer diagnosis and therapy. These include the mechanisms of customized drug load/release and synergistic effects in theranostics of these materials. Meanwhile, elucidations of key proteins’ roles in cancer development are also anticipated. Lastly, we hope that this topic can brew new ideas for the adaption of nanomaterials as platforms that allow for multimodal therapeutic modalities. The current Research Topic centers on the design, precise synthesis, and biomedical applications of nanomaterials. It aims to cover novel and promising research trends in nanomaterials with different morphology for cancer theranostics. Manuscripts from the following aspects, but not limited to, are welcomed: • Tailoring of asymmetrically structured (bowl-shaped, Janus, Yin Yang-like) polymer-inorganic nanomaterials; • Inorganic functional nanocrystals and functionalized mesoporous nanomaterials; • Design and synthesis of functional biomaterials, including lipids, polymers, and 2D materials • Non-viral DNA/mRNA delivery or drug/molecular inhibitor delivery; • Synthesizing biomaterials with novel nanostructures such as bowl-shaped, core-shell, spherical, Janus, and quantum dots; • Conquering drug resistance issues, tumor metastasis, and recurrence, as well as designing combination nanomedicines; • Dissecting the role of menin in prostate cancer and breast cancer: crosstalk between menin and AR signaling; • Multi-stimulus-responsive drug release and biological molecules.
Self-assembling biomaterials: molecular design, characterization and application in biology and medicine provides a comprehensive coverage on an emerging area of biomaterials science, spanning from conceptual designs to advanced characterization tools and applications of self-assembling biomaterials, and compiling the recent developments in the field. Molecular self-assembly, the autonomous organization of molecules, is ubiquitous in living organisms and intrinsic to biological structures and function. Not surprisingly, the exciting field of engineering artificial self-assembling biomaterials often finds inspiration in Biology. More important, materials that self-assemble speak the language of life and can be designed to seamlessly integrate with the biological environment, offering unique engineering opportunities in bionanotechnology. The book is divided in five parts, comprising design of molecular building blocks for self-assembly; exclusive features of self-assembling biomaterials; specific methods and techniques to predict, investigate and characterize self-assembly and formed assemblies; different approaches for controlling self-assembly across multiple length scales and the nano/micro/macroscopic properties of biomaterials; diverse range of applications in biomedicine, including drug delivery, theranostics, cell culture and tissue regeneration. Written by researchers working in self-assembling biomaterials, it addresses a specific need within the Biomaterials scientific community. - Explores both theoretical and practical aspects of self-assembly in biomaterials - Includes a dedicated section on characterization techniques, specific for self-assembling biomaterials - Examines the use of dynamic self-assembling biomaterials
With the emergence of additive manufacturing, mass customization of biomaterials for complex tissue regeneration and targeted drug delivery applications is possible. This book emphasizes the fundamental concepts of biomaterials science, their structure–property relationships and processing methods, and biological responses in biomedical engineering. It focuses on recent advancements in biomedical applications, such as tissue engineering, wound healing, drug delivery, cancer treatments, bioimaging, and theranostics. This book: Discusses design chemistry, modification, and processing of biomaterials Describes the efficacy of biomaterials at various scales for biological response and drug delivery Demonstrates technological advances from conventional to additive manufacturing Covers future of biofabrication and customized medical devices This volume serves as a go-to reference on functional biomaterials and is ideal for multi-disciplinary communities such as students and research professionals in materials science, biomedical engineering, healthcare, and medical fields.
This book is a printed edition of the Special Issue "Novel Biomaterials for Tissue Engineering 2018" that was published in IJMS
Research and new tools in biomaterials development by using peptides are currently growing, as more functional and versatile building blocks are used to design a host of functional biomaterials via chemical modifications for health care applications. It is a field that is attracting researchers from across soft matter science, molecular engineering and biomaterials science. Covering the fundamental concepts of self-assembly, design and synthesis of peptides, this book will provide a solid introduction to the field for those interested in developing functional biomaterials by using peptide derivatives. The bioactive nature of the peptides and their physical properties are discussed in various applications in biomedicine. This book will help researchers and students working in biomaterials and biomedicine fields and help their understanding of modulating biological processes for disease diagnosis and treatments.
This book explores in depth a wide range of functional biomaterials-based systems for drug, gene delivery, and biomedical aspects. The chapters cover newer technologies such as polymeric micelle, pH-responsive biomaterials, stimuli-responsive hydrogels, silk fibroin, inorganic biomaterials, synthetic biomaterials, 3D printed biomaterials, metallic biomaterials, ceramic and hybrid biomaterials. It also describes the theranostic approaches for cancer therapy, the biomaterials-based nanofibers scaffolds in tissue engineering, as well as the strategies applications of metallic biomaterials for the medical and dental prosthetic field. This newer and updated approach will be attractive for biomedical engineering students working on materials science in the development of novel drug delivery strategies. The book will be an important reference for researchers and professionals working on biomaterial research in the pharmaceutical and medical fields.
Hydrogels are crosslinked, macromolecular polymeric materials arranged in a three-dimensional network, which can absorb and retain large amounts of water. Hydrogels are commonly used in clinical practice and experimental medicine for a wide range of applications, including drug delivery, tissue engineering and regenerative medicine, diagnostics, cellular immobilization, separation of biomolecules or cells, and barrier materials to regulate biological adhesions. This book elucidates the underlying concepts and emerging applications of hydrogels and will provide key case studies and critical analysis of the existing research.
The development, processing, and applications of smart materials presents many challenges, including performance correlations to the nature of their reinforcement and the sustainability of such materials through their recyclability, durability, and reparability. Experts have identified the challenge of achieving sustainable development and in this book highlight how smart materials can provide a solution to the problem. It emphasizes the multidisciplinary nature of smart materials and their potential for enhancing product functionalities and capabilities in different sectors, including the biomedical, pharmaceutical, aerospace, construction, automotive, and food industries. Modeling, Characterization, and Processing of Smart Materials proposes a comprehensive guide to addressing the challenges associated with smart materials, including the need for optimization and sustainability, and provides various nature-inspired algorithms, computational and simulation approaches, and artificial intelligence-based strategies for developing innovative smart materials. It also presents potential solutions for the limitations of smart materials and emphasizes the role of Industry 4.0 in maintaining their sustainability. Overall, this book offers a valuable problem-solution perspective on the development and applications of smart materials, making it an essential reference guide for academic researchers and industrial engineers in the fields of material science, chemical engineering, and environmental engineering.
A succinct handbook explaining interdisciplinary processing, methods, and applications of bio-based materials This book merges the two most important trends in biomaterials: functionalization and renewable chemistry. It covers a variety of biopolymers and various approaches for the transformation of these biopolymers into functional units. Sample topics covered by the two well-qualified authors include: Fundamental knowledge of biopolymers–natural ones, such as cellulose and other polysaccharides, and synthetic ones, such as polyethylene The origin, classifications, chemical nature, and isolation methods of specific biopolymers The different classical and modern approaches for the transformation of biopolymers into different shapes, ranging from thin films (model surfaces), to nanoparticles, to nanofibers, all the way to 3D scaffolds The morphology, structure, shape, thermal, electrical, and surface properties of biomaterials This all-inclusive reference guide, which covers fundamentals, methods, and applications alike, is a key resource for both students and practicing scientists involved in programs of study or disciplines that intersect with the field of biomaterials.
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