Quantitative phase microscopy (QPM) leverages forward-scattered light and can detect structures at the microscale (in this study, over 100 nanometers), but not smaller. Consequently, this technique ...

Nearly 100 years ago, a seemingly simple discovery revolutionized the microscope. The introduction of phase contrast, which ...

Light waves, as they propagate through a medium, experience a temporal delay. This delay can unveil crucial information about the underlying structural and compositional characteristics. Quantitative ...

Image by the US National Institutes of Health, CC 3.0 A new dual-light microscope lets researchers observe micro- and nanoscale activity inside living cells without using dyes. The system, from the ...

For decades, imaging weakly scattering phase objects such as cells has been an active area of research across various fields, including biomedical sciences. One common approach uses chemical stains or ...

Early diagnosis and noninvasive monitoring of neurological disorders require sensitivity to elusive cellular-level alterations that emerge much earlier than volumetric changes observable with ...

A project at the University of Tokyo has developed a bidirectional scattering microscopy technique for imaging complex cell structures. Discussed in Nature Communications, the platform is designed to ...

An AI-powered toolkit automatically extracts and quantifies microstructural features from microscopy images, accelerating data-driven materials discovery and optimization. (Nanowerk News) A research ...

Conceptual illustration of the bidirectional quantitative scattering microscope, which detects both forward and backward scattered light from cells. This dual detection enables visualization of ...