Biomaterials, Medical Devices and Tissue Engineering: An Integrated Approach


Book Description

are then selected and must meet the general 'biocompatibility' require ments. Prototypes are built and tested to include biocompatibility evalua tions based on ASTM standard procedures. The device is validated for sterility and freedom from pyrogens before it can be tested on animals or humans. Medical devices are classified as class I, II or III depending on their invasiveness. Class I devices can be marketed by submitting notification to the FDA. Class II and III devices require either that they show equivalence to a device marketed prior to 1976 or that they receive pre-marketing approval. The time from device conception to FDA approval can range from months (class I device) to in excess of ten years (class III device). Therefore, much planning is necessary to pick the best regulatory approach. 2. Wound Dressings and Skin Replacement 2.1 Introduction Wounds to the skin are encountered every day. Minor skin wounds cause some pain, but these wounds will heal by themselves in time. Even though many minor wounds heal effectively without scarring in the absence of treatment, they heal more rapidly if they are kept clean and moist. Devices such as Band-Aids are used to assist in wound healing. For deeper wounds, a variety of wound dressings have been developed including cell cultured artificial skin. These materials are intended to promote healing of skin damaged or removed as a result of skin grafting, ulceration, burns, cancer excision or mechanical trauma.







Biomaterials, Medical Devices and Tissue Engineering: An Integrated Approach


Book Description

are then selected and must meet the general 'biocompatibility' require ments. Prototypes are built and tested to include biocompatibility evalua tions based on ASTM standard procedures. The device is validated for sterility and freedom from pyrogens before it can be tested on animals or humans. Medical devices are classified as class I, II or III depending on their invasiveness. Class I devices can be marketed by submitting notification to the FDA. Class II and III devices require either that they show equivalence to a device marketed prior to 1976 or that they receive pre-marketing approval. The time from device conception to FDA approval can range from months (class I device) to in excess of ten years (class III device). Therefore, much planning is necessary to pick the best regulatory approach. 2. Wound Dressings and Skin Replacement 2.1 Introduction Wounds to the skin are encountered every day. Minor skin wounds cause some pain, but these wounds will heal by themselves in time. Even though many minor wounds heal effectively without scarring in the absence of treatment, they heal more rapidly if they are kept clean and moist. Devices such as Band-Aids are used to assist in wound healing. For deeper wounds, a variety of wound dressings have been developed including cell cultured artificial skin. These materials are intended to promote healing of skin damaged or removed as a result of skin grafting, ulceration, burns, cancer excision or mechanical trauma.




Biomaterials Science


Book Description

"This book is essential when designing, developing and studying biomedical materials. provides an excellent review-from a patient, disease, and even genetic point of view-of materials engineering for the biomedical field. This well presented book strongly insists on how the materials can influence patients' needs, the ultimate drive for biomedic




Biomaterials in Translational Medicine


Book Description

Biomaterials in Translational Medicine delivers timely and detailed information on the latest advances in biomaterials and their role and impact in translational medicine. Key topics addressed include the properties and functions of these materials and how they might be applied for clinical diagnosis and treatment. Particular emphasis is placed on basic fundamentals, biomaterial formulations, design principles, fabrication techniques and transitioning bench-to-bed clinical applications. The book is an essential reference resource for researchers, clinicians, materials scientists, engineers and anyone involved in the future development of innovative biomaterials that drive advancement in translational medicine. - Systematically introduces the fundamental principles, rationales and methodologies of creating or improving biomaterials in the context of translational medicine - Includes the translational or commercialization status of these new biomaterials - Provides the reader with enough background knowledge for a fundamental grip of the difficulties and technicalities of using biomaterial translational medicine - Directs the reader on how to find other up-to-date sources (i.e. peer reviewed journals) in the field of translational medicine and biomaterials




Encyclopedia of Biomaterials and Biomedical Engineering


Book Description

Written by more than 400 subject experts representing diverse academic and applied domains, this multidisciplinary resource surveys the vanguard of biomaterials and biomedical engineering technologies utilizing biomaterials that lead to quality-of-life improvements. Building on traditional engineering principles, it serves to bridge advances in materials science, life sciences, nanotechnology, and cell biology to innovations in solving medical problems with applications in tissue engineering, prosthetics, drug delivery, biosensors, and medical devices. In nearly 300 entries, this four-volume Encyclopedia of Biomaterials and Biomedical Engineering, Second Edition, covers: essential topics integral to tissue engineering research: bioreactors, scaffolding materials and fabrication, tissue mechanics, cellular interaction, and development of major tissues and organs being attempted by researchers worldwide; artificial lungs and muscles, bio-artificial livers, and corneal, dental, inner ear, and total hip implants; tissue engineering of blood vessels, heart valves, ligaments, microvascular networks, skeletal muscle, and skin; bone remodeling, bone cement, and bioabsorbable bone plates and screws; controlled drug delivery, insulin delivery, and transdermal and ocular implant-based drug delivery; endovascular stent grafts, vascular grafts, and xenografts; 3-D medical imaging, electrical impedance imaging, and intravascular ultrasound; biomedical, protein adsorption, and in vivo cardiovascular modeling; polymer foams, biofunctional and conductive polymers, and electroactive polymeric materials; blood–material interactions, the bone–implant interface, host reactions, and foreign body responses and much more.




Biomaterials for Tissue Engineering


Book Description

This volume reviews the published knowledge about bioactive composites, protein scaffolds and hydrogels. Chapters also detail the production parameters and clarify the evaluation protocol for analysis or testing and scaffolding biomaterials. The volume concludes with a summary of applications of porous scaffold in medicine. Each chapter links basic scientific and engineering concepts to practical applications for the benefit of the reader. The text offers a wealth of information that will be of use to all students, bioengineers, materials scientists, chemists, physicians and surgeons concerned with the properties, performance, and the application of tissue engineering scaffolds in clinical settings.




Mechanics of Biomaterials


Book Description

Combining materials science, mechanics, implant design and clinical applications, this self-contained text provides a complete grounding to the field.




Biodegradable Systems in Tissue Engineering and Regenerative Medicine


Book Description

Conventional materials technology has yielded clear improvements in regenerative medicine. Ideally, however, a replacement material should mimic the living tissue mechanically, chemically, biologically and functionally. The use of tissue-engineered products based on novel biodegradable polymeric systems will lead to dramatic improvements in health




Managing Medical Devices within a Regulatory Framework


Book Description

Managing Medical Devices within a Regulatory Framework helps administrators, designers, manufacturers, clinical engineers, and biomedical support staff to navigate worldwide regulation, carefully consider the parameters for medical equipment patient safety, anticipate problems with equipment, and efficiently manage medical device acquisition budgets throughout the total product life cycle. This contributed book contains perspectives from industry professionals and academics providing a comprehensive look at health technology management (HTM) best practices for medical records management, interoperability between and among devices outside of healthcare, and the dynamics of implementation of new devices. Various chapters advise on how to achieve patient confidentiality compliance for medical devices and their software, discuss legal issues surrounding device use in the hospital environment of care, the impact of device failures on patient safety, methods to advance skillsets for HTM professionals, and resources to assess digital technology. The authors bring forth relevant challenges and demonstrate how management can foster increased clinical and non-clinical collaboration to enhance patient outcomes and the bottom line by translating the regulatory impact on operational requirements. - Covers compliance with FDA and CE regulations, plus EU directives for service and maintenance of medical devices - Provides operational and clinical practice recommendations in regard to regulatory changes for risk management - Discusses best practices for equipment procurement and maintenance - Provides guidance on dealing with the challenge of medical records management and compliance with patient confidentiality using information from medical devices