Super-resolution fluorescence microscopy has transformed our ability to visualise biological structures at the nanoscale by breaking the classical diffraction barrier of light. Traditional optical ...

There is a growing demand for non-invasive insights into the complex three-dimensional subcellular dynamics within living tissues at the frontier of biological research. Professor Xi Peng's group at ...

Bredt’s rule-inspired, bridged bicycle-strengthened fluorescent dyes resist both photobleaching and photoblueing, offering a powerful new toolkit for super-resolution fluorescence microscopy. This ...

A breakthrough in imaging technology promises to transform our understanding of the inner workings of living cells, and provide insights into a wide range of diseases. "It's like taking an airplane ...

To unravel the complexities of biological phenomena, scientists have long relied on microscopy to visualize the intricate details of their specimens, including tissue architecture, cell morphology, ...

When single-molecule super-resolution microscopes were first commercialized some 15 years ago, they made headlines for their ability to resolve individual molecules and structures at the nanometer ...

With the rapid revolution in super-resolution microscopy, the resolution of far-field optical microscopy has entered the sub-nanometer era, providing new insights into macromolecules in vitro and in ...

Even those who maintain that super-resolution microscopy is a powerful tool of biological discovery have admitted that it may have a bit of an image problem. For example, in a recent review, several ...

The brain relies on real-time delivery of oxygen and nutrients through its microvasculature, which threads through neural tissue like electrical wires. While modern imaging technologies allow ...

Fluorescence nanoscopy has transformed our ability to visualize and discover biological structures. In recent years, ultraprecise single-molecule localization techniques such as MINFLUX and RASTMIN ...