Watching proteins move as they drive the chemical reactions that sustain life is one of the grand challenges of modern ...

A fabrication process can produce self-heating microfluidic devices in one step using a multimaterial 3D printer. These devices, which can be made rapidly and cheaply in large numbers, could help ...

Researchers have unveiled a microfluidic device that significantly improves the separation of tumor cells and clusters from malignant effusions. This novel technology promises to advance the diagnosis ...

According to MarketsandMarkets™, the Microfluidics Market is projected to grow from about USD 24.96 billion in 2025 to USD 37.2 billion by 2030, at a CAGR of 8.3%.

Microfluidics is a powerful technique for modulating the fluidic behavior of bioparticles in microscale channels and has opened up new avenues for biomedical research and clinical diagnosis.

A cheap one-step process produces miniature chemical reactors that could be used to detect diseases or analyze substances. MIT researchers have used 3D printing to produce self-heating microfluidic ...

Researchers have developed a groundbreaking, freely available droplet microfluidic component library, which promises to transform the way microfluidic devices are created. This innovation, based on ...

Old-school electrical engineers—and plenty of older research scientists, even biologists like me—remember the days of building circuits from parts: capacitors, resistors, and transistors. The creation ...

The beverage industry continually seeks innovative methods to ensure product quality, safety, and compliance with global health standards. Microfluidic devices have emerged as a pivotal technology in ...

MIT researchers developed a fabrication process to produce self-heating microfluidic devices in one step using a multi-material 3D printer. Pictured is an example of one of the devices. MIT ...