Since its emergence, microfluidics technology has proven to be a powerful tool in connecting the engineering world to the life sciences. Life on our plants depends on the exchange of nano or picolitres of fluid to its building blocks called cells. To understand many thousands of microfluidics phenomena regulating, governing or dictating life nothing works better than Microfluidics. Microfluidics is not a branch of science, engineering or art. It is rather a collection of collaborative effort enabled by multidisciplinary engineers and used by curious scientists. That said, applications of microfluidics is numerous. Ready to learn more about how microfluidic devices are helping in academic research and the industry? Check out our collection of microfluidics applications below!
Organ-on-a-chip is one of the most popular microfluidic chips. Click on the link below to learn more about these microfluidics chips!
Microfluidic cell sorter and cell separation chips are highly effective, modular, and cost-effective which rely on microfluidics principles.
Explore the various aspects of C. elegans research that have been impacted by microfluidic technology and microfluidics.
Microfluidic gene delivery chips are capable of transferring genetic or chemical cargo into the cells at higher efficiencies using microfluidics means.
Droplet-based microfluidics is a powerful tool for ultra-high-throughput assays in biology and chemistry.
Microparticle and microfibers are applicable in various microfluidics applications such as drug delivery and tissue engineering.
Microfluidic technology provides a suitable platform for Point-Of-Care microfluidics applications in diagnostics and environmental testing.
Microfluidics offers highly precise and controlled environments for analyzing the performance of a new drug compound.
Sperm selection and semen analysis are two aspects of fertility aid where microfluidics can play an important role.
Microfluidics helps in isolating circulating tumor cells (CTCs) as potential determinants of cancer prognosis.
Microfluidic systems are capable of delivering precise doses of compounds to the body as well as producing drug carriers.
Microfluidic technology is a suitable choice for non-isothermal and isothermal nucleic acid amplification methods.
Microfluidics technology offers powerful tools for enhancing microarray assays and microarray patterning techniques.
Microfluidics enhances the strengths of organoids as 3D functional replicas of the organs.
Single-cell analysis has become one of the most important applications of microfluidic technology in recent years.
Mircrofluidics technology can empower regenerative medicine research in a variety of ways.
Microfluidic chips offer novel and efficient approaches for isolation, detection, and analysis of exosomes.