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 ...

Microfluidic biochips represent a transformative technology that miniaturises laboratory functions onto single chip platforms, revolutionising biochemical assays, point‐of‐care diagnostics, and ...

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 ...

Aerosol jet printing process for surface acoustic wave (SAW) microfluidic devices. a Schematic of the fabrication process and mechanism of the aerosol jet-printed SAW microfluidic devices.

Microfluidics involves fluid manipulation and control at a submillimeter scale within microfabricated channels etched on a chip, forming a miniature laboratory capable of performing complex analytical ...

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 ...

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 ...

A tiny microfluidic device can improve cell therapy techniques for spinal cord injury patients. The device can remove a large percentage of stem cells that have not yet fully become spinal cord cells, ...

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) Surface Acoustic Wave (SAW) technologies, known for their high precision and rapid actuation, are essential to microfluidics and affect a broad spectrum of research areas. However, ...