Biomolecular condensates are shifting blobs in our cells that organize cellular matter. They are distinct molecular ...
Computational microscopy is vital in biomedicine and materials science. Traditional methods struggle with optical aberrations ...
The way we study plant cells is expanding—literally—thanks to new research from Kevin Cox, an assistant professor of biology ...
Researchers shed new light on G-quadruplexes, a type of secondary DNA structure that has attracted attention as a potential therapeutic target in cancer.
Researchers tested computational predictions by peering into condensates using novel super-resolution microscopy methods.
Scientists at Lab are unraveling the mysteries of Bennu, a 4.5-billion-year-old asteroid, using cutting-edge technology. The ...
Growing up, Dr. Melody Campbell, 38, was part of the Campbell Quartet. Little did she know, she’d embark on a career to lead ...
The global photoacoustic microscopy market is on a strong growth trajectory, with projections indicating a significant rise in market value. By 2024, the market is expected to reach USD 120 billion, ...
A new approach for Brillouin microscopy has improved the speed and throughput 1000-fold, offering a quicker method to explore ...
Conventional microscopes are limited in their resolution to 200 nm at the lowest. However, many interesting processes occur ...
Imagine a microscopic locomotive moving back and forth along a track, propelling itself without any external force. At the molecular level, this concept forms the foundation of molecular motors -- ...