In an interview with Jay Salazar from Panther Life Sciences, we discuss microarray patch (MAP) technology and its potential ...

Controlling light at the micro- and nanoscale opens up opportunities for a better understanding of the world and the development of technology. As modern electronics approaches the limits of its ...

Mass spectrometry is already a powerful tool for determining what kind and how many molecules are present in a given sample. But most instruments still analyze their molecules one or just a few at a ...

Understand the importance of targeted assays in personalised medicine and how early decisions shape clinical outcomes.

Malaria parasites contain tiny spinning crystals that have puzzled scientists for years. New research reveals they’re powered by a rocket-like reaction that breaks down hydrogen peroxide, releasing ...

With Raman microscopy, there's an additional layer of complexity: fluorescence. Particle fluorescence can overwhelm the Raman signal and make routine analysis more challenging. In comparison, IR ...

Discover how CRISPR genome editing is revolutionizing medicine. Learn the science of Cas9, current clinical trials, and the future of gene editing.

A team of international researchers have developed a breakthrough way to observe what is happening inside electronic chips while they are operating—without touching them, taking them apart, or ...

Scientists can now do research on live human organs without petri dishes or animal testing.

A bandage-like microneedle patch can noninvasively collect immune cells and signals from the skin within minutes to hours. Early tests suggest it could transform how immune responses are monitored.

Long before nanotechnology existed, Richard Feynman explained how atoms could store huge amounts of information in microscopic spaces.

Engineers at Duke University have demonstrated a technique that uses microbubbles and ultrasound to help relatively large cancer drugs enter tumor cells and cause them to self-destruct.