Poly(vinyl chloride) (PVC) is the most widely used polymer in today's healthcare market. It is still the polymer of choice for single use presterilised medical devices after more than 50 years of service and it continues to dominate in cost-performance terms. This book will prove to be a mine of useful and practical information for healthcare professionals, medical device manufacturers and medical polymer producers.
"This is a Ph.D. dissertation. Historically, occupational interstitial lung disease was common in workers who had inhaled mineral dusts such as silica, asbestos, and coal. With improved industrial hygiene and reduced mining and use of these agents, heavy e"
Undoubtedly the applications of polymers are rapidly evolving. Technology is continually changing and quickly advancing as polymers are needed to solve a variety of day-to-day challenges leading to improvements in quality of life. The Encyclopedia of Polymer Applications presents state-of-the-art research and development on the applications of polymers. This groundbreaking work provides important overviews to help stimulate further advancements in all areas of polymers. This comprehensive multi-volume reference includes articles contributed from a diverse and global team of renowned researchers. It offers a broad-based perspective on a multitude of topics in a variety of applications, as well as detailed research information, figures, tables, illustrations, and references. The encyclopedia provides introductions, classifications, properties, selection, types, technologies, shelf-life, recycling, testing and applications for each of the entries where applicable. It features critical content for both novices and experts including, engineers, scientists (polymer scientists, materials scientists, biomedical engineers, macromolecular chemists), researchers, and students, as well as interested readers in academia, industry, and research institutions.
No book has been published that gives a detailed description of all the types of plastic materials used in medical devices, the unique requirements that the materials need to comply with and the ways standard plastics can be modified to meet such needs. This book will start with an introduction to medical devices, their classification and some of the regulations (both US and global) that affect their design, production and sale. A couple of chapters will focus on all the requirements that plastics need to meet for medical device applications. The subsequent chapters describe the various types of plastic materials, their properties profiles, the advantages and disadvantages for medical device applications, the techniques by which their properties can be enhanced, and real-world examples of their use. Comparative tables will allow readers to find the right classes of materials suitable for their applications or new product development needs.
Plastics in Medical Devices: Properties, Requirements, and Applications, Third Edition provides a comprehensive overview on the main types of plastics used in medical device applications. The book focuses on the applications and properties that are most important in medical device design, such as chemical resistance, sterilization capability and biocompatibility. The roles of additives, stabilizers and fillers as well as the synthesis and production of polymers are covered and backed up with a wealth of data tables. The book also covers other key aspects in detail, including regulations, compliance, purchasing controls and supplier controls, and process validation. This updated edition has been thoroughly revised with regard to new plastic materials, applications and requirements. This is a valuable resource for engineers, scientists and managers involved in the design and manufacture of medical devices. - Presents detailed coverage of commercially available plastics used in medical device applications, organized by polymer type and supported by data - Includes up-to-date regulatory requirements and practical information on purchasing and supplier controls, process validation and risk management - Supports the development, marketing and commercialization of medical devices and materials for use in medical devices
Applications of Polymers and Plastics in Medical Devices: Design, Manufacture, and Performance is a comprehensive guide to plastic materials for medical devices, covering fundamentals, materials, applications and regulatory requirements. Sections cover the role of plastics in medical devices, socioeconomic factors, the classification of medical devices. The performance of, medical grades and suppliers of polymer materials, which are categorized by performance level are also explored, along with manufacturing processes for device components, including extrusion, casting, injection molding and assembly processes. The book then covers applications in detail, examining each device and the role that polymers and plastics play in its construction and function. This is an essential resource for engineers, R&D, and other professionals working on plastics for medical devices and those in the plastics industry, medical device manufacturing, pharmaceuticals, packaging and biotechnology. In an academic setting, this book is of interest to researchers and advanced students in medical plastics, plastics engineering, polymer science, mechanical engineering, chemical engineering, biomedical engineering and materials science. - Offers systematic coverage of the major classes of polymers used in medical devices, including properties, characteristics, performance, medical grades and suppliers - Reviews regulatory requirements of the FDA and other global agencies, as well as considering quality control and socioeconomic factors - Includes the latest advances in plastics for medical devices, such as novel applications, use of bio-based polymers, and processing of reusable medical devices
In recent years there have been certain scare stories about the possible negative effects on human health from some of these materials. However, today, it is realised that it is often not the polymers themselves, but their monomers or the additives used that are responsible for these negative effects. And the reality is that a lot of polymers are used in medical applications without adverse effects on patients. Hence, the dividing line between whether something is toxic and harmful to health or not (and if it is, under what conditions) is a very critical issue and therefore, there needs to be a better understanding of these systems. This book presents the available information on the eternal triangle of plastics and rubber and health, to enable a better understanding of the facts.
This review describes the process of life cycle analysis in some detail. It describes the different organisations involved in researching and applying these techniques and the database resources being used to generate comparative reports. The overview explains the factors to be considered, the terminology, the organisations involved in developing these techniques and the legislation which is driving the whole process forward. The ISO standards relating to environmental management are also discussed briefly in the document. Design for the environment is covered in the report. This review is accompanied by summaries of selected papers on life cycle analysis and environmental impact from the Rapra Polymer Library database.
The health sector is known to be one of the major contributors towards the greenhouse gas emissions causing the climate crisis, the greatest health threat of the 21st century. This volume positions the health sector as a leader in the fight against climate change and explores the role of the health system in climate policy action. It delivers an overview of the linkages between climate change and the health sector, with chapters on the impact of climate change on health, its connection to pandemics, and its effects on food, nutrition and air quality, while examining gendered and other vulnerabilities. It delves into the different operational aspects of the health sector in India and details how each one can become climate-smart to reduce the health sector’s overall carbon footprint, by looking at sustainable procurement, green and resilient healthcare infrastructure, and the management of transportation, energy, water, waste, chemicals, pharmaceuticals and plastics in healthcare. Well supplemented with rigorous case studies, the book will be indispensable for students, teachers, and researchers of environmental studies, health sciences and climate change. It will be useful for healthcare workers, public health officials, healthcare leaders, policy planners and those interested in climate resilience and preparedness in the health sector. The Open Access version of this book, available at http://www.taylorfrancis.com, has been made available under a Creative Commons Attribution-Non Commercial-No Derivatives 4.0 license.
