Ch. 1. A microscale bioinspired cochlear-like sensor / Robert D. White, Robert Littrell, and Karl Grosh -- ch. 2. Systematic evaluation of the efficiencies of proteins and chemicals in pharmaceutical applications / Morgan Hamon and Jong Wook Hong -- ch. 3. Microfluidic glucose sensors / Jithesh V. Veetil [und weitere] -- ch. 4. Applications of microfabrication and microfluidic techniques in mesenchymal stem cell research / Abhijit Majumder [und weitere] -- ch. 5. Patient-specific modeling of low-density lipoprotein transport in coronary arteries / Ufuk Olgac -- ch. 6. Point-of-care microdevices for global health diagnostics of infectious diseases / Sau Yin Chin [und weitere] -- ch. 7. Integrated microfluidic sample preparation for chip-based molecular diagnostics / Jane Y. Zhang [und weitere] -- ch. 8. Microfluidic devices for cellular proteomic studies / Yihong Zhan and Chang Lu -- ch. 9. Microfluidics for neuroscience: novel tools and future implications / Vivian M. Hernandez and P. Hande Ozdinler -- ch. 10. Microfluidics: on-chip platforms as in vitro disease models / Shan Gao, Erkin Seker, and Martin L. Yarmush -- ch. 11. Application of microfluidics in stem cell and tissue engineering / Sasha H. Bakhru, Christopher Highley, and Stefan Zappe -- ch. 12. Microfluidic "on-the-fly" fabrication of microstructures for biomedical applications / Edward Kang, Sau Fung Wong, and Sang-Hoon Lee -- ch. 13. Microfluidics as a promising tool toward distributed viral detection / Elodie Sollier and Dino Di Carlo -- ch. 14. Electrophoresis and dielectrophoresis for lab-on-a-chip (LOC) analyses / Yagmur Demircan, Gurkan Yilmaz, and Haluk Kulah -- ch. 15. Ultrasonic embossing of carbon nanotubes for the fabrication of polymer microfluidic chips for DNA sample purification / Puttachat Khuntontong, Min Gong, and Zhiping Wang -- ch. 16. Ferrofluidics / A. Rezzan Kose and Hur Koser -- ch. 17. Antibody-based blood bioparticle capture and separation using microfluidics for global health / ZhengYuan Luo [und weitere] -- ch. 18. Applications of quantum dots for fluorescence imaging in biomedical research / ShuQi Wang [und weitere]

The field of microfluidics has in the last decade permeated many disciplines, from physics to biology and chemistry, and from bioengineering to medical research. One of the most important applications of lab-on-a-chip devices in medicine and related disciplines is disease diagnostics, which involves steps from biological sample/analyte loading to storage, detection, and analysis. The chapters collected in this book detail recent advances in these processes using microfluidic devices and systems. The reviews of portable devices for diagnostic purposes are likely to evoke interest and raise new research questions in interdisciplinary fields (e.g., efficient MEMS/microfluidic engineering driven by biological and medical applications).The variety of the selected topics (general relevance of microfluidics in medical and bioengineering research, fabrication, advances in on-chip sample detection and analysis, and specific disease models) ensures that each of them can be viewed in the larger context of microfluidic-mediated diagnostics.

The fields of microfluidics and BioMEMS are significantly impacting cell biology research and applications through the application of engineering solutions to human disease and health problems. The dimensions of microfluidic channels are well suited to the physical scale of biological cells, and the many advantages of microfluidics make it an attractive platform for new techniques in biology. This new professional reference applies the techniques of microsystems to cell culture applications. The authors provide a thoroughly practical guide to the principles of microfluidic device design and operation and their application to cell culture techniques. The resulting book is crammed with strategies and techniques that can be immediately deployed in the lab. Equally, the insights into cell culture applications will provide those involved in traditional microfluidics and BioMEMS with an understanding of the specific demands and opportunities presented by biological applications. The goal is to guide new and interested researchers and technology developers to the important areas and state-of-the-practice strategies that will enhance the efficiency and value of their technologies, devices and biomedical products.

According to a report from the U.S. Centers for Disease Control and Prevention (CDC), achieving safe and healthier foods was one of the top ten achievements of public health in the 20th century. However, considerable persisting challenges currently exist in developed nations and developing economies for further assuring the safety and security of the food supplies. According to CDC estimates, as many as 3000 American adults, as an example, and based on a recent epidemiological estimate of the World Health Organization, around 420,000 individuals around the globe, lose their lives annually due to foodborne diseases. This emphasizes the need for innovative and emerging interventions, for further prevention or mitigation of the risk of foodborne microbial pathogens during food processing and manufacturing. The current publication discusses recent advancements and progress in the elimination and decontamination of microbial pathogens during various stages of manufacturing and production. Special emphasis is placed on hurdle validation studies, investigating decontamination of non-typhoidal Salmonella enterica serovars, various serogroups of Shiga toxin-producing Escherichia coli, public health-significant serotypes of Listeria monocytogenes, and pathogenic species of Cronobacter.

This book presents the selected peer-reviewed papers from the National Conference on Advances in Mechanical Engineering (NCAME 2019), held at the National Institute of Technology Delhi, India. The book covers different areas of mechanical engineering from design engineering to manufacturing engineering. A wide range of topics are discussed such as CAD/CAM, additive manufacturing, fluid dynamics, materials science and engineering, simulation and modeling, finite element analysis, applied mechanics to name a few. The contents provide an overview of the state-of-the-art in mechanical engineering research in the country. Given the scope of the topics covered, the book will be of interest for students, researchers and professionals working in mechanical engineering.

Responding to the need for an affordable, easy-to-read textbook that introduces microfluidics to undergraduate and postgraduate students, this concise book will provide a broad overview of the important theoretical and practical aspects of microfluidics and lab-on-a-chip, as well as its applications.

Laboratory Methods in Microfluidics features a range of lab methods and techniques necessary to fully understand microfluidic technology applications. Microfluidics deals with the manipulation of small volumes of fluids at sub-millimeter scale domain channels. This exciting new field is becoming an increasingly popular subject both for research and education in various disciplines of science, including chemistry, chemical engineering and environmental science. The unique properties of microfluidic technologies, such as rapid sample processing and precise control of fluids in assay have made them attractive candidates to replace traditional experimental approaches. Practical for students, instructors, and researchers, this book provides a much-needed, comprehensive new laboratory reference in this rapidly growing and exciting new field of research. - Provides a number of detailed methods and instructions for experiments in microfluidics - Features an appendix that highlights several standard laboratory techniques, including reagent preparation plus a list of materials vendors for quick reference - Authored by a microfluidics expert with nearly a decade of research on the subject