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

With the continuous advancement of biomedical research toward high-throughput, precision, and personalized approaches, ...

Novel techniques, automated machines, sophisticated synthetic and bioprospected polymerases, and developments in symbiotic sequencing technologies have transformed PCR into a multifaceted, adaptable ...

Researchers developed a microfluidic chip with 3D-printed microstructures that moves droplets precisely, captures cells efficiently, and quickly forms cell spheroids for improved lab-grown tissue ...

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, ...

Most cells in the human body exist in complex three-dimensional environments, yet they are still commonly studied on flat ...

Monitoring cancer cells effectively can help physicians with treatment and management, thus reducing cancer-related mortality. Can non-invasive technologies pave the way for improved monitoring to ...

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 ...

Advanced in vitro models such as organ-on-chip systems aim to replicate human physiology more accurately than conventional cell cultures. However, most existing platforms struggle to incorporate ...