Recent developments in microfluidics have demonstrated enormous potential of microscale cell culture for biology studies and recognized as instrumental in performing rapid and efficient experiments on small-sample volumes. Microfluidic-based cell culture is an area of research that keeps growing and gaining importance as a prominent technology, able to link scientific disciplines with industrial and clinical applications. In particular, organotypic cell culture and its integration in microfluidic devices would enable the realization of “in vivo-like” cell microenvironment within systems that are more amenable to automation and integration. Such remarkable advancement forms the foundation and motivation to transfer research from the laboratory to the field. Although the microfluidics and cell culture technologies have influenced many areas of science, significant research efforts are currently focus on finding methods to transform drug screening and toxicity testing from a system reliant on high-dose animal studies to one based primarily on human-relevant in vitro models. In line with regulatory developments precluding the use of animal testing, as well as fundamental differences in animal versus human, human in vitro methodologies are required to replace the animal-based testes while permitting physiologically relevant model equivalents for superior prediction. Organs-on-a-chip is an ambitious and rapidly growing technology that promise to bridge the gap between in vivo and in vitro studies and open wide possibilities in medical and industrial applications. However, many challenges are still ahead. This eBook present recent state-of-the-art works and critical reviews in organs-on-a-chip technology which highlight the new advances in this growing field with an emphasis on the interface between technological advancements and high impact applications.

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.

Techniques for microfabricating intricate microfluidic structures that mimic the microenvironment of tissues and organs, combined with the development of biomaterials with carefully engineered surface properties, have enabled new paradigms in and cell culture-based models for human diseases. The dimensions of surface features and fluidic channels made accessible by these techniques are well-suited to the size scale of biological cells. Microfluidic Cell Culture Systems applies design and experimental techniques used in in microfluidics, and cell culture technologies to organ-on-chip systems. This book is intended to serve as a professional reference, providing a practical guide to design and fabrication of microfluidic systems and biomaterials for use in cell culture systems and human organ models. The book covers topics ranging from academic first principles of microfluidic design, to clinical translation strategies for cell culture protocols. The goal is to help professionals coming from an engineering background to adapt their expertise for use in cell culture and organ models applications, and likewise to help biologists to design and employ microfluidic technologies in their cell culture systems. This 2nd edition contains new material that strengthens the focus on in vitro models useful for drug discovery and development. One new chapter reviews liver organ models from an industry perspective, while others cover new technologies for scaling these models and for multi-organ systems. Other new chapters highlight the development of organ models and systems for specific applications in disease modeling and drug safety. Previous chapters have been revised to reflect the latest advances. - Provides design and operation methodology for microfluidic and microfabricated materials and devices for organ-on-chip disease and safety models. This is a rapidly expanding field that will continue to grow along with advances in cell biology and microfluidics technologies. - Comprehensively covers strategies and techniques ranging from academic first principles to industrial scale-up approaches. Readers will gain insight into cell-material interactions, microfluidic flow, and design principles. - Offers three fundamental types of information: 1) design principles, 2) operation techniques, and 3) background information/perspectives. The book is carefully designed to strike a balance between these three areas, so it will be of use to a broad range of readers with different technical interests and educational levels.

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]

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

Recent advances in microsystems technology and cell culture techniques have led to the development of organ-on-chip microdevices that produce tissue-level functionality, not possible with conventional culture models, by recapitulating natural tissue architecture and microenvironmental cues within microfluidic devices. Since the physiological microenvironments in living systems are mostly microfluidic in nature, the use of microfluidic devices facilitates engineering cellular microenvironments; the microfluidic devices allow for control of local chemical gradients and dynamic mechanical forces, which play important roles in cellular viability and function. The organ-on-chip microdevices have great potential to promote drug discovery and development, to model human physiology and disease, and to replace animal models for efficacy and toxicity testing. Recently, induced pluripotent stem (iPS) cells have been leveraged to develop organs-on-chips, which enable various types of organ models and disease models not possible with primary cells and cell lines. This Special Issue seeks to showcase research papers, short communications, and review articles that focus on: (1) microdevices to mimic or control cellular microenvironment; (2) microdevices to evaluate interactions between different organ models; (3) microdevices to maintain iPS cells or iPSC-derived cells; and (4) sensors and techniques to evaluate drug efficacy or toxicity.

Biochip technology has experienced explosive growth in recent years and Biochip technology describes the basic manufacturing and fabrication processes and the current range of applications of these chips. Top scientists from the biochip industry and related areas explain the diverse applications of biochips in gene sequencing, expression monitoring, disease diagnosis, tumor examination, ligand assay and drug discovery.