Next-Generation Antimicrobial Nanocoatings for Medical Devices and Implants provides a detailed, up-to-date overview of nano-based antimicrobial coatings used to combat medical device-related biofilms. An introduction to biofilms and how they infect medical devices is included, as well as strategies/modification techniques used to target these biofilms. This book evaluates the various antimicrobial coatings formed using nanomaterials such as silver, inorganic materials, organic materials, carbon dots, surfactants, and electrospun fibers, specifically for us on medical devices and implants. Numerous coating methods are discussed along with the biological characterizations of these coating materials, and their toxicological and environmental impact.Next-generation Antimicrobial Nanocoatings for Medical Devices and Implants is a useful reference for materials scientists, biomedical engineers, and those working on the development of novel biomaterials for use in medical devices and implants.

Biomedical Product and Materials Evaluation: Standards and Ethics provides a much-needed overview of the procedures, issues, standards and ethical issues in the early development of biomedical products. The book covers a range of key biomedical products, from 3D printed organs and blood derived products, to stem calls and decellularized tissue products. Each chapter reviews a single product type, associated materials, biomedical applications, proven development strategies, and potential challenges. The core focus of the book is on the standardization and ethical aspects of biomedical product development, with these elements addressed and discussed in chapters dedicated to product evaluation. This is a useful reference for academics, researchers and industry professionals in R&D groups with an interest in biomaterial research and production, as well as those working in the fields of biomedical engineering, biotechnology and toxicology.

This book highlights the application of microfluidics in cell biology research, chemical biology, and drug discovery. It covers the recent breakthroughs and prospects of organ-on-a-chip, human-on-a-chip, multi-organ-on-a-chip for personalized medicine. The book presents the preclinical studies of organs-on-a-chip, concepts of multiple vascularized organ-on-chips, application of organ-on-a-chip in blood-brain barrier model, culture and co-culture of cells on multi-organ-on-chip and parameter measurements in microfluidic devices. It underscores the advantage of microfluidic devices for developing efficient drug carrier particles, cell-free protein synthesis systems, and rapid techniques for direct drug screening. Further, it entails human-on-a-chip for measuring the systemic response as well as immediate effects of an organ reaction on other organs. In summary, this book reviews the development of a microfluidic-based organ-on-a-chip device for the preclinical evaluation, ADME studies of drugs, chemicals, and medical devices. This book is a valuable source for pharma companies, product developers, students, researchers, academicians, and practitioners.