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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 methodologiesProvides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applicationsPresents 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 methodologiesProvides comprehensive coverage of electrospun/spray materials in drug delivery, tissue engineering and biosensor applicationsPresents details of instrumentation involved, along with novel devices for bench to bedside translationCovers novel combinational approaches using electrospinning, electrospraying and 3D printing
Polymeric Biomaterials for Healthcare Applications details a broad range of polymeric biomaterials, methods of synthesis and preparation, and their various applications in healthcare and biomedicine. The book provides a fundamental overview of polymers and processing technologies to allow clinical scientists to explore the use of these polymers in alternative applications. A wide variety of healthcare applications are covered, including treatment for autoimmune diseases and bacterial infections, tissue engineering, gene delivery, wound dressing, and more. The book provides a core introductory text for clinical and materials scientists new to the area of polymeric biomaterials. This book will prove useful to academics and researchers in materials science, biomedical engineering, clinical science and pharmaceutical science. Covers a broad range of polymeric biomaterials, including chitosan, alginate, cellulose, collagen, synthetic conjugates, and more Details a wide variety of healthcare applications for polymeric biomaterials, such as orthopedic engineering, antibiotics, targeted drug delivery, and more Provides a detailed overview of polymer processing technologies and sterilization considerations
Nanomaterials for Photodynamic Therapy takes a unique approach to this area, with a key focus on the use of nanomaterials and nanocarriers for photodynamic therapy (PDT). The book introduces the history and mechanism of action behind PDT, covering the variety of sensitizers currently available. Subsequent chapters review existing and emerging nanomaterials for PDT, including hydrogel nanocomposites, fullerenes, quantum dots, polymeric micelles, and more. Challenges and translational aspects of PDT are also discussed, touching on the issues and hindrances of drug resistant cancers. The book bridges the gap between the physics and clinical aspects of PDT, offering a unique nanomaterials-focused perspective. This book will prove useful for materials scientists, biomedical engineers, electrical and optical engineers, and pharmaceutical scientists interested in cancer treatment.
Biomaterials for Angiogenesis and Vasculogenesis covers the application of materials designed to encourage new blood vessel formation. Angiogenesis and vasculogenesis play an important role in tissue engineering and regenerative medicine research by promoting vascular networks inside engineered tissues and thereby increasing tissue healing and regeneration. However, researchers are faced with the challenge of finding suitable materials for improving angiogenesis and vascular formation in assays. This book reviews a broad range of biomaterials for the promotion of blood vessel genesis, from polymers and bioactive glass, to nanomaterial scaffolds and 3D angiogenic constructs. In addition, the book covers a variety of applications for biomaterials in tissue repair and regeneration, including cardiovascular regeneration, liver tissue engineering and much more. It will serve as a detailed reference for researchers in academia and industry, working in the fields of biomedical science and engineering, materials science, regenerative medicine and translational medicine. Introduces readers to the molecular and cellular basis of angiogenesis and vasculogenesis Helps researchers find suitable biomaterials to promote angiogenesis in engineered tissues and assays Describes a range of biomaterials and their properties, including glass-ceramics, nano-carriers, polymers, and more
Polymeric Micelles for Drug Delivery provides a comprehensive overview on the synthesis, characterization and application of polymeric micelles in drug delivery applications. The use of nanomedicines and carriers, such as polymeric micelles, has made it possible to deliver drugs, genes and therapeutic agents to localized disease sites to maximize clinical benefit while limiting unwanted side effects. This book thoroughly reviews the development and application of polymeric micelles for drug delivery, covering various polymer types and the synthesis, characterization and pharmacokinetics of different micelles. Subsequent chapters go on to look at the range of drug delivery applications of polymeric micelles - such as mucosal and transdermal - and the assorted stimuli-responsive micelles available. The book concludes with an important analysis of the environmental and regulatory aspects associated with micelle development and clinical translation. Explores how polymeric micelles can be utilized in a range of different drug delivery approaches, from traditional oral delivery to ocular and dermal delivery Describes the various polymer types used in the synthesis and characterization of polymeric micelles Covers recent advances in polymeric micelles, such as drug co-delivery, triblock polymeric micelles, delivery of genetic materials, and more
Immunomodulatory Effects of Nanomaterials: Assessment and Analysis provides an overview of the modulatory impact of nanomaterials on the immune system, as well as evaluative and analytical methods for assessing effects. Sections cover a range of common nanomaterials for biomedical use and how different properties can elicit varied responses from the immune system. The immunomodulatory effects of these materials are then discussed, with coverage on adverse and/or toxic effects on the immune system, as well as desired modulatory effects to improve efficacy of applied therapeutics. Readers will also learn about the best evaluation methods for immunomodulatory effects of nanomaterials and associated risks. This book is a useful reference for academics and researchers with an interest in immunology, but it is also idea for those working in the fields of materials science, biomedical engineering, pharmaceutical science, immunology and toxicology. Details a range of common nanomaterials and how their specific properties and characteristics interact with the immune system Discusses the immunomodulatory effects of nanomaterials, from unintentional and potentially harmful, to intentional and desired effects on the immune system Explores methods for evaluation of immunomodulatory effects of nanomaterials, as well as precautions and risks for data analysis and interpretation
Biomaterials for Neural Tissue Engineering covers a range of materials and technologies used for regenerating or repairing neural tissue. With a strong focus on biomaterials and scaffolds, the book examines the testing and evaluation pathway for in-vitro and in-vivo testing trials. This book introduces the reader to the fundamentals of the nervous system from a tissue engineering perspective and goes on to describe contemporary technologies used in the development of neural repair materials, as well as currently available biomaterials suitable for neural tissue repair and regeneration. This detailed reference is ideal for those who are new to using biomaterials in tissue engineering, particularly those interested in the nervous system, including academics and early career researchers in the fields of materials science, regenerative medicine, biomedical engineering and clinical sciences.
3D Printing in Medicine, Second Edition examines the rapidly growing market of 3D-printed biomaterials and their clinical applications. With a particular focus on both commercial and premarket tools, the book looks at their applications within medicine and the future outlook for the field. The chapters are written by field experts actively engaged in educational and research activities at the top universities in the world. The earlier chapters cover the fundamentals of 3D printing, including topics such as materials and hardware. The later chapters go on to cover innovative applications within medicine such as computational analysis of 3D printed constructs, personalized 3D printing - including 3D cell and organ printing and the role of AI - with a subsequent look at the applications of high-resolution printing, 3D printing in diagnostics, drug development, 4D printing, and much more. This updated new edition features completely revised content, with additional new chapters covering organs-on-chips, bioprinting regulations and standards, intellectual properties, and socio-ethical implications of organs-on-demand.
Polymeric Materials for Biomedical Implants: Characterization, Properties, and Applications offers a comprehensive guide to the various polymers utilized in the development and application of biomedical implants. These materials possess unique properties which make them ideal for use in biomedical implants, including their high degree of flexibility, ease of fabrication, non-magnetic and radio transparent properties for medical imaging, and ease of engineering for biocompatibility. The book thoroughly reviews the properties, characterization and a broad range of applications of polymeric materials in biomedical implants, bringing all key information on this important topic together under a single reference. The book's chapters cover vital topics for the development of polymeric biomedical implants, including biomaterial-tissue interactions, mechanical and surface property requirements for different implants, as well as market and ethical issues. This will be a useful reference for academics and researchers working in materials science, biomedical engineering, regenerative medicine and pharmacology, as well as R&D groups developing biomedical implants.
Natural Biopolymers for Drug Delivery thoroughly details the properties, benefits and challenges of using these biomaterials in drug delivery, with a strong focus on biocompatibility and reduction of unwanted interactions. An extensive range of natural biopolymers are explored, such as cellulose, chitosan, casein, gelatin, cashew gum, and many more. Biocompatibility, toxicity and regulatory considerations are also thoroughly discussed, ensuring the reader is fully equipped for efficient biomaterials selection and utilization in drug delivery applications. This is a must-have reference for those working in the fields of materials science, biomedical engineering, pharmaceutical science and pharmacology, chemical engineering and clinical science.
Nanotechnology in Herbal Medicine: Applications and Innovations details how nanomaterials can be utilized to improve the therapeutic mechanisms and key properties of herbal drugs. This book guides the reader through the preparation, properties, applications, benefits and challenges of herbal nanoformulations, helping them solve fundamental and applied problems in the area of novel herbal medicines and drug delivery systems. Herbal drugs play a large role in traditional medicines, which are actively used by many cultures across the globe for the treatment of various illnesses and injuries. Despite their widespread use, herbal medicines may lead to possible health risks due to the lack of information on the chemical composition and permitted dosage.
Bioresorbable Polymers and their Composites: Characterization and Fundamental Processing for Pharmaceutical and Medical Device Development provides a holistic view of these unique materials and their usage in a range of biomedical applications. The book is evenly divided between fundamentals, processing methods and modeling approaches, and includes detailed coverage of a variety of applications, such as drug delivery, medical devices and wound healing. Key aspects including biocompatibility, biodegradability and toxicology are also thoroughly covered, enabling the reader to be fully informed when fabricating and utilizing their selected bioresorbable polymer. This book is an interdisciplinary and important reference for researchers in the fields of materials science, biomedical engineering, pharmaceutical science and regenerative medicine, as well as R&D groups in the development of medical devices.
Bioengineered Nanomaterials for Wound Healing and Infection Control is a key reference for those working in the fields of materials science, pharmacy, nanotechnology, biomedical engineering and microbiology. Bioengineered nanomaterials have unique physicochemical properties which promote accelerated wound healing and treatment of infections. The biosynthesis of these nanomaterials also offers a clean, safe and renewable alternative to traditional nanomaterials, helping reduce environmental impact alongside antibacterial resistance.
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