Stanford researchers have combined two microscopy techniques to create a one-of-a-kind instrument that can show cell ...

Not all defects are visible with the same microscope. Explore how resolution, contrast, and signal interpretation shape ...

The rapid evolution of microscopy techniques has transformed our ability to visualise biological structures and processes at unprecedented resolutions. Advances in live‐cell imaging, super‐resolution ...

Scientists have developed a new imaging technique that uses a novel contrast mechanism in bioimaging to merge the strengths of two powerful microscopy methods, allowing researchers to see both the ...

In this article, we look at some of the key developments of various microscopy techniques over the last few years and how they have benefitted different areas of research and development. The impact ...

Nanoscopy is a field of microscopy that focuses on imaging and studying structures and processes at the nanoscale, typically below the diffraction limit of light. It encompasses various techniques ...

Chemotherapy is a powerful weapon against cancer, but certain cells resist treatment by entering a dormant stage called senescence. These therapy-induced senescent (TIS) cells may become resistant to ...

One variation of electron microscopy is transmission electron microscopy (TEM). In a TEM experiment, the electron beam passes through the sample and the electrons are directly imaged onto an electron ...

Explore advances in protein imaging techniques and spatial proteomics. Learn how modern imaging tools reveal protein dynamics and organization in cells.

What is the Diffraction Limit? The diffraction limit is a fundamental barrier in optical microscopy that sets the minimum size of features that can be resolved using conventional light microscopes. It ...

Researchers at the University of Illinois at Urbana-Champaign have shown for the first time that expensive aberration-corrected microscopes are no longer required to achieve record-breaking ...