The current anthology reflects this new paradigm, examining issues surrounding the use of medical plastics through the mutifaceted lens of chemical and biomedical engineering, microbiology, toxicology, nanochemistry, physics, and informatics. Historically, plastics as biomaterials have been reviewed almost entirely in the context of surgical implants. The collection of chapters that follows surveys a broader, newer array of applications for medical plastics that includes diagnostic equipment, product packaging, drug delivery devices, and tissue regeneration. These novel uses for plastics have translated into a surge in the volume of medical devices and equipment being employed around the world. Newer technologies, such as medical molding and packaging, have been responsible for much of the growth in the past several years. However, traditional applications of medical plastics continue to drive the industry forward as well. For example, 300,000 people around the world undergo cardiac valve replacement every year [2]. And in 2011, more than 150 million people wore silicone or hydrogel-based contact lenses, a 25% rise from a decade earlier [3]. The increasing demand for these products has led to an economic resurgence for the field as a whole. Although medical products still only account for 1% of the plastics market share, the consumption of medical devices has tripled in the past decade to become a $300 billion global industry [4]. Over the next several years, the business of biological implants is expected to grow by 7% annually [5]. These trends are in large part a consequence of an aging population, a rising prevalence of chronic diseases, and a shift from invasive surgeries toward minimally invasive implantation procedures.