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.

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]

This dissertation discusses the applications for open microfluidics in emerging technologies for studying human health and the environment. Open microfluidics is a sub-field of microfluidics that is quickly gaining traction for technologies across biology and the environment. The open nature of the microchannels enables flexibility to the user for adding or removing components and makes it simple to use. Chapter 1 introduces how microfluidics has traditionally been used and provides a background of open microfluidics and the common methods used to fabricate devices. Chapter 2 evaluates rapid injection molding, a more economical version of traditional injection molding, for open microfluidic cell-based technologies. Minimum dimensions and dimension accuracy are investigated for applications with fluorescence imaging. Chapter 3 highlights a novel method for generating droplets in an open microfluidic device that utilizes natural hydrostatic pressure and therefore does not require pumps or external equipment to generate the droplets. Additionally, potential use cases are presented for applications in droplet manipulation, patterning, splitting, and fusion. Chapter 4 presents a layer-by-layer hydrogel patterning method made possible by spontaneous capillary flow. An open microfluidic rail-based device is used to pattern entire layers of hydrogels for biological applications in tissue engineering, organoid development, and 3D cell culture. Chapter 5 presents a novel method for capturing airborne particles using microdroplets and open microfluidic channels for shuttling the collected sample across the device. The work presented here demonstrates fundamental open microfluidic principles for droplet generation and fabrication as well as how open microfluidics can be applied to diverse fields of study such as hydrogel patterning and environmental sampling.

The increasing threats of emerging and reemerging infectious disease outbreaks demand research and development (R&D) of effective and fit-for-all-purpose tools and technologies for international public health security. Recent advances in biomedical engineering, mostly related to the convergence of communication and network technology in health, i.e., mobile health with microfluidic Lab-on-a-Chip technology can improve the international public health crises and employ in international public health security. Lab-on-a-Chip technology is now commonly found in most research centers, hospitals, and clinics where health care infrastructure is weak, and access to quality and timely medical care is challenging. Microfluidic devices,Äîalso known as Lab-on-a-Chip (LoC),Äîare an alternative for accessible, cost-effective, and early detection medical trials. The mHealth-based microfluidic LoC technology has been under rapid development, and they are becoming influential tools in a wide range of biomedical research and international public health applications. The perspective in this chapter demonstrates a potentially transformative opportunity for the deployment of mHealth with LoC with the fabrication protocols and their potential for strengthening and improving the international public health security. This attempt is not conclusive and exhaustive, and it is anticipated that such a discussion will enable the exchange of ideas between biomedical engineering, microfluidic LoC technology professionals, international public health, and health security experts.

Microfluidics have aroused a new surge of interest in recent years in environmental and energy areas, and inspired novel applications to tackle the worldwide challenges for sustainable development. This book aims to present readers with a valuable compendium of significant advances in applying the multidisciplinary microfluidic technologies to address energy and environmental problems in a plethora of areas such as environmental monitoring and detection, new nanofluid application in traditional mechanical manufacturing processes, development of novel biosensors, and thermal management. This book will provide a new perspective to the understanding of the ever-growing importance of microfluidics.

Micro/Nanofluidics and Lab-on-Chip Based Emerging Technologies for Biomedical and Translational Research Applications - Part B, Volume 187 represents the collation of chapters written by eminent scientists worldwide. Chapters in this new release include Design and fabrication of microfluidics devices for molecular biology applications, Micro/Nanofluidics devices for drug delivery, From organ-on-chip to body-on-chip: the next generation of microfluidics platforms for in vitro drug toxicity testing, Micro/Nanofluidics for high throughput drug screening, Design, fabrication and assembly of lab-on-a-chip and its uses, Advances in microfluidic 3D cell culture for pre-clinical drug development, Tissue and organ culture on lab-on-a chip for biomedical applications, and much more. Offers a basic understanding of the state-of-the-art design and fabrication of microfluidics/ nanofluidics and lab on chip Explains how to develop microfluidics/nanofluidic for advanced application such as healthcare, high throughout drug screening, 3D cell culture and organ-on-chip Discusses the emerging demands and research of micro/nanofluidic based devices in biomedical and translational research applications

Microfluidics or lab-on-a-chip (LOC) is an important technology suitable for numerous applications from drug delivery to tissue engineering. Microfluidic devices for biomedical applications discusses the fundamentals of microfluidics and explores in detail a wide range of medical applications. The first part of the book reviews the fundamentals of microfluidic technologies for biomedical applications with chapters focussing on the materials and methods for microfabrication, microfluidic actuation mechanisms and digital microfluidic technologies. Chapters in part two examine applications in drug discovery and controlled-delivery including micro needles. Part three considers applications of microfluidic devices in cellular analysis and manipulation, tissue engineering and their role in developing tissue scaffolds and stem cell engineering. The final part of the book covers the applications of microfluidic devices in diagnostic sensing, including genetic analysis, low-cost bioassays, viral detection, and radio chemical synthesis. Microfluidic devices for biomedical applications is an essential reference for medical device manufacturers, scientists and researchers concerned with microfluidics in the field of biomedical applications and life-science industries.