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Electrofluidodynamic Technologies (EFDTs) for Biomaterials and Medical Devices: Principles and Advances focuses on the fundamentals of EFDTs - namely electrospinning, electrospraying and electrodynamic atomization - to develop active platforms made of synthetic or natural polymers for use in tissue engineering, restoration and therapeutic treatments. The first part of this book deals with main technological aspects of EFDTs, such as basic technologies and the role of process parameters. The second part addresses applications of EFDTs in biomedical fields, with chapters on their application in tissue engineering, molecular delivery and implantable devices. This book is a valuable resource for materials scientists, biomedical engineers and clinicians alike. - Presents a complete picture of Electrofluidodynamic technologies and their use in biomedicine - Provides a comprehensive, professional reference on the subject, covering materials processing, fabrication and the use of novel devices for tissue engineering and therapeutics - Focuses on technological advances, with an emphasis on studies and clinical trials
This book provides a contemporary research-led overview of the applications of inorganic materials in biomedicine. It begins with a short introduction summarising key concepts in inorganic materials (layered materials, framework materials etc.), and explaining the need for new materials in medicine. It then discusses the key areas in which inorganic materials have been applied, considering: drug delivery; imaging; diagnostics and theranostics; hard matter restoration; and vaccines. Each chapter gives an overview of the major extant challenges in the research area, before presenting a systematic review of how inorganic materials have been applied to gain traction in the field. A clear focus is maintained on the fate of the applied materials in vivo, clinical considerations, and the path to translation from lab to clinic. With contributions from leading researchers, Biomedical Applications of Inorganic Materials will provide a comprehensive introduction for advanced undergraduates, postgraduates and researchers wishing to learn about the topic.
The aim of this book is to explore the history, fundamentals, manufacturing processes, optimization parameters, and applications of electrospun materials. The book includes various types of electrospun materials such as antimicrobial, smart, bioinspired systems. It focuses on the many application areas for electrospun materials such as energy storage and harvesting, catalysis, biomedical including gene delivery and tissue engineering, separation, adsorption and water treatment technologies, packaging. The book emphasizes the enhanced sustainable properties of electrospun materials, with the challenges and future developments being discussed in detail. The chapters are written by top-class researchers and experts from throughout the world.
This book addresses the limitations of existing therapeutic approaches using nanoparticles. Emerging Roles of Nanocarriers in Cancer Therapy will further provide information for the development of successful cancer nanomedicine therapies. Features Explains different types of nanoparticles, targeting mechanisms, and approved nanotherapeutics for oncological implications in cancer treatment. Covers in detail the characteristics of various nanotechnology-based drug delivery systems. Discusses passive and active cellular targeting, ligand-based targeting of nanoparticles, and strategies to improve nanoparticle-cellular membrane interaction. Presents the application of nanotherapeutics, current challenges, and prospects, and describes the path of future research. Highlights smart strategies for improving the clinical impact of cancer nanomedicine. The text is primarily written for graduate students, and academic researchers in the fields of biotechnology, nanotechnology, drug delivery, pharmaceutical science, and pharmacology.
The sustainability of any process lies in the eco-friendly and economical production of products for applications. Bio-based materials are emerging as raw materials for different products and applications. The book covers cellulose, chitosan, silk, collagen and gelatin bio-based materials. It describes their use in biomedical applications, such as orthopaedic implant, drug delivery, tissue culture, biosensor and engineering applications such as fuel cells, energy storage and packaging. It concludes with the use of bio-based materials as precursors for biorefinery, biolubricants, membranes and adsorbents.
This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact.
In vitro, in vivo, and in silico preclinical models hold a widely acknowledged potential, yet complex limitations. For this reason, which has been known for a long time by experimenters and modelers, the translation of “science products” to the clinic is still far. Therefore, there is a raising awareness of the need to bridge this gap by developing integrated and innovative models. Organ and tissue bioengineering is an ideal approach to foster innovative strategies in significant research and clinical areas. Similarly, in translational neuroscience research, this challenge has been taken up by intriguing fish models. However, much research based on novel methodologies has still to be performed to get the bench closer to the bedside.
Biomedical Applications of Electrospinning and Electrospraying describes the principles and laboratory set up for electrospinning and electrospraying, addressing a range of biomedical applications. Sections cover novel combinational approaches, such as electrospinning/spraying and 3D printing. Electrospinning has evolved from being a technique to prepare random networks of textile fibers to a technique to fabricate highly ordered patterns of biomedical materials of defined scale. The technological advancements in recent years with regard to the way the jet is facilitated, how the jet path is controlled, and how the fibers are collected have provided invaluable insights into controlled fabrication of a material of choice. Additionally, the electrospray technique has also evolved from being a technique to prepare food formulations to a technique to prepare cell encapsulated beads for transplantation in clinics. Several innovations in this line, such as those leading to core-shell materials have tremendously changed the way the technique is used. Thus, a combinational approach using electrospinning, electrospraying and 3D printing has emerged. - Introduces electrospinning and electrospraying concepts and describes state-of-the-art methodologies - Provides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applications - Presents details of instrumentation involved, along with novel devices for bench to bedside translation, - Covers novel combinational approaches using electrospinning, electrospraying and 3D printingIntroduces electrospinning and electrospraying concepts and describes state-of-the-art methodologies - Provides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applications - Presents details of instrumentation involved, along with novel devices for bench to bedside translation - Covers novel combinational approaches using electrospinning, electrospraying and 3D printing
Frontiers in Oncology is delighted to present the Methods in series of article collections. Methods in Head and Neck Cancer will publish high-quality methodical studies on key topics in the field. It aims to highlight recent advances in the field, whilst emphasizing important directions and new possibilities for future inquiries. The Methods in Head and Neck Cancer collection aims to highlight the latest experimental techniques and methods used to investigate fundamental questions in Head and Neck Cancer. Review Articles or Opinion Articles on methodologies or applications including the advantages and limitations of each are welcome. This Research Topic includes technologies and up-to-date methods which help aim to help advance science.
This book presents the development of electrospun materials, fundamental principles of electrospinning process, controlling parameters, electrospinning strategies, and electrospun nanofibrous structures with specific properties for applications in tissue engineering and regenerative medicine, textile, water treatment, sensor, and energy fields. This book can broadly be divided into three parts: the first comprises basic principles of electrospinning process, general requirements of electrospun materials and advancement in electrospinning technology, the second part describes the applications of electrospun materials in different fields and future prospects, while the third part describes applications that can be used in advanced manufacturing based on conjoining electrospinning and 3D printing. Electrospinning is the most successful process for producing functional nanofibers and nanofibrous membranes with superior chemical and physical properties. The unique properties of electrospun materials including high surface to volume ratio, flexibility, high mechanical strength, high porosity, and adjustable nanofiber and pore size distribution make them potential candidates in a wide range of applications in biomedical and engineering areas. Electrospinning is becoming more efficient and more specialized in order to produce particular fiber types with tunable diameter and morphology, tunable characteristics, having specific patterns and 3D structures. With a strong focus on fundamental materials science and engineering, this book provides systematic and comprehensive coverage of the recent developments and novel perspectives of electrospun materials. This comprehensive book includes chapters that discuss the latest and emerging applications of nanofiber technology in various fields, specifically in areas such as wearable textile, biomedical applications, energy generation and storage, water treatment and environmental remediation, and sensors such as biomarkers in healthcare and biomedical engineering. Despite all these advancements, there are still challenges to be addressed and overcome for nanofiber technology to move towards maturation.