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 ...

Microscopy continues to transform the life sciences. Here are five recent breakthroughs made possible by the technique.

Global health is changing as a result of developments in life sciences research and technology, and these advancements have the potential to offer innovative and improved approaches to promote a ...

Researchers at Istituto Italiano di Tecnologia (IIT-Italian Institute of Technology) have developed an innovative microscopy ...

In a recent article published in Nature Communications, researchers introduced NanoPlex, a novel strategy designed to overcome limitations in fluorescence microscopy ...

The MEMS confocal unit can be connected to an inverted microscope to allow for confocal fluorescence imaging. Depending on the needs, the MAICO line-up provides three variations with varying ...

Two-photon microscopy is a type of fluorescence microscopy that, rather than exciting the sample with a single photon, makes use of multiple photons. The advantage over more traditional one-photon ...

Fluorescence microscopy is a cornerstone of modern biological research, widely used to reveal cellular structures, molecular interactions, and dynamic life processes. Computational fluorescence ...

This seminar provides an overview of fluorescence microscopy in cancer research and other cell-based applications in the biosciences discovery workflow. In comparison with phase contrast and ...

Light microscopy is a key tool that scientists use to image cells, organelles, subcellular structures, and molecules such as proteins and nucleic acids. Because visible light leaves biological ...

Integrating deep learning in optical microscopy enhances image analysis, overcoming traditional limitations and improving classification and segmentation tasks.