Where to Buy Microfluidic Device
The microfluidic device market is classified into different segments. The diagnostic & treatment segment holds the largest market share. Diagnostic devices and chips are used for various purposes, including drug discovery and high-throughput screening. Microfluidic devices are also used in point-of-care diagnostics, such as glucose tests, pregnancy tests, and other types of molecular testing. These devices have great potential in the diagnosis of many diseases.
This device has the potential to bring instant tests for diseases and illnesses into the homes of the average consumer. It can also detect toxic gases and contaminants in food. But despite the potential, microfluidic devices are still largely limited to researchers' labs. Engineers at the University of Michigan have aimed to change that. They have developed a microfluidic device kit with 16 pieces to make the device more affordable for the general public. Mark Burns, professor of Biomedical and Chemical Engineering at the University of Michigan, has collaborated with graduate student Minsoung Rhee to develop the kit.
Microfluidic devices are available in various shapes and sizes and are constructed of different materials. They can be connected to standard fluidic equipment, allowing researchers to use them for analysis. In some cases, researchers glue commercial micro-tube fittings to the ports of microfluidic devices. However, this method is complicated and can clog the port. In addition, it may lead to contamination. Therefore, if you're looking for a microfluidic device, you need to look for a reliable distributor. Find more information about microfluidic devices here.
The microfluidic devices market is likely to grow slowly in the Middle East and Africa, as awareness about microfluidic technology is low in those regions. Lack of funding and infrastructure facilities will limit the market for microfluidic devices in this region. One private company focusing on affordable, high-quality PDMS-based microfluidic devices is uFluidix. This company also uses a quality management system for product development and reliability. Its expertise in manufacturing chips made from thermoplastics and polydimethylsiloxane are an added bonus.
In addition to the benefits listed above, another advantage of lab-on-a-chip systems is their high analytical flexibility. They're small enough to fit in a pocket, but powerful enough to mimic the human body. For example, they can be used to grow cells and study diseases. This innovation could also improve the quality of life for patients. A patient can get genetic tests without having to undergo painful procedures. This technology could revolutionize the way in which we test our cells. Learn more about this in this article.
The science of microfluidics is a fascinating and innovative technology that is making breakthroughs in science and technology. The invention of inkjet printhead technology during the 1950s and 1960s has provided the foundation for microfluidics. Meanwhile, computers were miniaturized for space exploration. During the same decade, the first microprocessors and integrated circuits were created. Using photolithography, these devices are small enough to be embedded in a chip and are a vital part of research. This link https://en.wikipedia.org/wiki/Digital_microfluidics will open up your minds even more on this topic.