This book explores the transformative power of critical literacy in fostering youth engagement through university-community partnerships. It is based on a six-year study by The Literacy and Community Initiative (LCI) at North Carolina State University. This book examines the potential, possibilities, and challenges of using critical literacy in university-community partnerships to amplify youth voices. Through the LCI program, youth in four community-based organizations completed a critical literacy curriculum, published their writings in a book, and participated in public readings to engage and lead their communities. The authors draw on data from semi-structured individual interviews, focus groups, youth narratives, and socio-emotional surveys across four unique youth populations. The youth populations involved collaborations with youth of color in urban communities, Latine immigrant and second-generation youth, girls in foster care and high-risk situations, and youth from immigrant and refugee backgrounds. Results of the study suggest that after engaging in the LCI critical literacy program, youth demonstrated improved literacy skills, enhanced social-emotional well-being, and increased community leadership and self-advocacy. Presenting a novel theoretical framework for the effective use of critical literacy to promote positive youth development in conjunction with first-hand insights into the successful development and sustainment of university-community research partnerships, this book ultimately provides a unique insight into how critical literacy and successful university-community partnerships can combine to result in powerful support for underserved culturally and linguistically diverse youth. This book will appeal to scholars, educators, and practitioners with interests in critical literacy, positive youth development studies, and adolescent research.
This book examines recent methods used for blood flow modeling and associated in vivo experiments, conducted using experimental data from medical imaging. Different strategies are proposed, from small-scale models to complex 3D modeling using modern computational codes. The geometries are wide-ranging and deal with the narrowing and widening of sections (stenoses, aneurysms), bifurcations, geometries associated with prosthetic elements, and even cases of vessels with smaller dimensions than those of the blood cells circulating in them. Biological Flow in Large Vessels provides answers to the question of how medical and biomechanical knowledge can be combined to address clinical problems. It offers guidance for further development of numerical models, as well as experimental protocols applied to clinical research, with tools that can be used in real-time and at the patient's bedside, for decision-making support, predicting the progression of pathologies, and planning personalized interventions.
The pioneering guide on the design, processing, and testing of antimicrobial plastic materials and coatings The manifestation of harmful microbes in plastic materials used in medical devices and drugs, water purification systems, hospital equipment, textiles, and food packaging pose alarming health threats to consumers by exposing them to many serious infectious diseases. As a result, high demand for intensifying efforts in the R&D of antimicrobial polymers has placed heavy reliance on both academia and industry to find viable solutions for producing safer plastic materials. To assist researchers and students in this endeavor, Antimicrobial Polymers explores coupling contaminant-deterring biocides and plastics—focusing particular attention on natural biocides and the nanofabrication of biocides. Each chapter is devoted to addressing a key technology employed to impart antimicrobial behavior to polymers, including chemical modification of the polymers themselves. A host of relevant topics, such as regulatory matters, human safety, and environmental risks are covered to help lend depth to the book's vital subject matter. In addition, Antimicrobial Polymers: Discusses the design, processing, and testing of antimicrobial plastic materials Covers interdisciplinary areas of chemistry and microbiology Includes applications in food packaging, medical devices, nanotechnology, and coatings Details regulations from the U.S. (FDA and EPA) and EU as well as human safety and environmental concerns Achieving cleaner and more effective methods for improving the infection-fighting properties of versatile and necessary plastic materials is a goal that stretches across many scientific fields. Antimicrobial Polymers combines all of this information into one volume, exposing readers to preventive strategies that harbor vast potential for making exposure to polymeric products and surfaces a far less risky undertaking in the future.
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