Microfluidics and Nanofluidics is an international peer reviewed journal exploring all aspects of microfluidics, nanofluidics, and lab-on-a-chip science and technology. The journal seeks to improve the fundamental understanding of microfluidic and nanofluidic processes, examining the current state of research and development and the latest applications.
Papers based biosensors such as lateral flow test strips and paper-based microfluidic devices are inexpensive, rapid, flexible, and easy-to-use analytical tools for point-of-care diagnosis. An.Microfluidics is a field of research that explores the handling of minute amounts of liquids in tiny micrometer scale channels. This approach can reduce sample and reagent consumption, harness benefits from the exquisite micro scale fluid physics, address small objects such as biological cells, but also reduce size and cost of chemical and biological instrumentation and improve overall.View Droplet Based Microfluidics Research Papers on Academia.edu for free.
Overview. Our Microfluidics and Microengineering Research Group performs both academic research into novel microengineered devices and techniques, and pursues business-facing projects involving consultancy and turnkey microfluidics-enabled systems for government agencies and industry.
Paper-based microfluidics can enable fluid handling and quantitative analysis for potential applications in healthcare, veterinary medicine, environmental monitoring and food safety. Currently, in its early development stages, paper-based microfluidics is considered a low-cost, lightweight, and disposable technology. Our research focuses on (i) fabrication of paper-based microfluidic devices.
The global microfluidics market size was evaluated at USD 13.5 billion in 2019 and is expected to register a CAGR of 11.3% through the forecast period. Rise in demand for point-of-care (POC) devices is expected to significantly drive the market. Microfluidics-based devices need a fraction of the sample for data interpretation. The application of microfluidics has enabled conventional.
For many of these applications, microfluidics and other MEMS technologies are essential, as they provide the functional basis of many research tools as well as commercial devices and applications. Thus, over the past several years, there has been a significant increase in the activities associated with understanding, development, and application of micromechanical and microfluidic devices and.
Microfluidics is a very active area of research. Scientists world-wide are publishing a myriad of articles describing mechanisms, designs, and applications. Listed here are a few selected papers which, in our view, provide an excellent introduction and insight into the field, along with additional subtopics of special interest. The authors have generously made these articles available through.
Our research teams span fields including engineering, physics, medicine and biology and are carrying out research into areas such as single cell analysis, organ-on-a-chip, neuroscience, clinical diagnostics, personalised medicine and environmental monitoring. Our scientists are now using microfluidics to find solutions to some of today’s biggest challenges including antimicrobial resistance.
Research: Group: Publications: Patents: Collaborations: Public Reports: Positions: Cover Pages: Photo Gallery: Microfluidics. 1. Development of microfluidic models of thromboembolism Our group has pioneered continuous microfluidic synthesis of polymer particles with exquisite control of their size, composition, shape and morphology (see our paper in Angew. Chem (2005) and follow up papers.
Paper-based microfluidics has also been used to conduct environmental and food safety tests. The main issues in the application of this technology are the lack of research into the flow control techniques, accuracy, and precision, the need for simpler operator procedures in the field, and the scaling of production to meet the volume requirements of a global market. This is largely due to the.
This volume provides an overview of the recent advances in the field of paper microfluidics, whose innumerable research domains have stimulated considerable efforts to the development of rapid, cost-effective and simplified point-of-care diagnostic systems. The book is divided into three parts viz. theoretical background of paper microfluidics, fabrication techniques for paper-based devices.
The Microfluidics and Microengineering Group has dedicated clean room and laboratory facilities located in the main building on the College Lane campus. The facilities include a 35m2 class 1000 (ISO 6) clean room and 100m2 of microfluidics laboratory for precision assembly and testing of microstructured devices and an aerosol testing facility for sample collection investigation.
Research Topic Recent Highlight Papers; Austria: Austrian Institute of Technology: Health and Environment - Nano Systems: lab-on-a-chip, sensors: Austria: Vienna University of Technology: Institute of Sensor and Actuator Systems (ISAS) microfluidics, optofluidics, physical chemosensors, on-chip electrophoresis, fluid mixing, single-cell analysis: Belgium: Ghent University: Research Group.
In diagnostics, microfluidics have made it possible to capture circulating tumour cells. 6,7. and to design progressively more sensitive and integrated point-of-care applications for chronic and infectious diseases using small volumes of biologically complex samples. 8. The field of microfluidics has experienced explosive growth in the past decade, and this trend is expected. to continue. The.
Microfluidics refers to the behaviour, precise control, and manipulation of fluids that are geometrically constrained to a small scale (typically sub-millimeter) at which capillary penetration governs mass transport. It is a multidisciplinary field that involves engineering, physics, chemistry, biochemistry, nanotechnology, and biotechnology.It has practical applications in the design of.
Microfluidics Research Group, Biophysics. Navigation bar. Home; Research; People; Research Activities. Research Activities. Droplet-based microfluidics. Traditional medical treatment of various cancer types can be more destructive than beneficial since the treatments come with a great cost of reduced quality of life; some procedures, such as chemo or radiation therapy, may even cause lethal.