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 ...

Microfluidics is an interdisciplinary field that combines principles from physics, chemistry, and engineering to create devices that can process and analyze minuscule volumes of liquids. Often, ...

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 ...

The field of microfluidics involves minute devices that precisely manipulate fluids at submillimeter scales. Such devices typically take the form of flat, two-dimensional chips, etched with tiny ...

Stephen Quake, a bioengineer and applied physicist at Stanford University, has always been interested in the interface between physics and biology. During his work at the California Institute of ...

With the continuous advancement of biomedical research toward high-throughput, precision, and personalized approaches, traditional experimental methods have shown obvious limitations in reaction ...

A research team from George R Brown School of Engineering and Computing (Rice University; TX, USA), led by Peter Lillehoj and Kevin Mchugh, have developed an innovative AI-enabled microfluidic ...

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 ...

(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 ...