Microfluidic devices have long been a staple in research settings for performing a variety of cell manipulation applications or for determining such material characteristics as viscosity, pH, and ...

The U.S. Microfluidic Devices Market was valued at USD 2.32 billion in 2025 and is expected to reach USD 4.53 billion by 2033, growing at a CAGR of 8.76%. This growth is fueled by the increasing ...

Scientists have developed a method to facilitate the creation and replication of small microfluidic devices, creating an easier manufacturing process for a range of do-it-yourself medical diagnostic ...

Devices with intricate interlacing channels, the width of a human hair, that move minuscule amounts of liquids, and can be used to diagnose and treat complex diseases, can now be made using a ...

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 ...

In a recent breakthrough, researchers from MIT have introduced an innovative technique involving multi-material 3D printing to create self-heating microfluidic devices. MIT researchers developed a ...

Understanding the nature of malignant effusions, teeming with tumor cells and clusters, is critical in comprehending the breadth of cancer's impact. The significant role of tumor clusters, with their ...

Microfluidic mixing techniques and devices are pivotal in advancing applications ranging from chemical synthesis to biomedical diagnostics. In these systems, liquids or gases are combined in channels ...

Dielectrophoresis (DEP) is an electrokinetic phenomenon that induces the motion of polarisable particles in a non-uniform electric field. This method, utilised within microfluidic devices, has evolved ...

Scientists from Japan and USA develop a microfluidic device for the purification of tuberculosis genomic DNA fragments from human-plasma samples In the war against cancer, the first step towards ...

(Nanowerk News) MIT researchers have used 3D printing to produce self-heating microfluidic devices, demonstrating a technique which could someday be used to rapidly create cheap, yet accurate, tools ...

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 ...