A team led by Raju Tomer, professor of biological sciences at Columbia University, has created a new design for microscopes ...

Researchers have developed a new type of microscope that can acquire extremely large, high-resolution pictures of non-flat objects in a single snapshot. This innovation could speed up research and ...

Deep inside a small, windowless room at the University of California, Berkeley, two microscopes are quietly capturing some of ...

In a study published in Science Advances, a research team led by Prof. Liu Chengbo from the Shenzhen Institutes of Advanced Technology (SIAT) of the Chinese Academy of Sciences developed a 1.7-gram ...

A new study introduces affordable HySIL lens technology and modular devices that deliver high-resolution 3D tissue imaging.

Researchers have developed a new two-photon fluorescence microscope that captures high-speed images of neural activity at cellular resolution. By imaging much faster and with less harm to brain tissue ...

Metalenses represent a revolutionary advancement in optical technology. Unlike conventional microscope objectives that rely on curved glass surfaces, metalenses employ nanoscale structures to ...

High quality label-free imaging of oocytes and early embryos is essential for accurate assessment of their developmental potential, a key element of assisted reproduction procedures. To achieve this ...

The availability and application of optical microscopy based on image sensors is rapidly increasing because of the high read-out rates combined with the high quantum efficiency of modern scientific ...

University researchers have developed a high-resolution microscope that is small enough to sit on a computer chip. The tiny microscope has the magnifying power of a top-quality optical microscope and ...

In-vivo imaging of the neuronal activity in mouse primary visual cortex. Left, high-resolution neuronal map; middle, high-speed neuronal activity recording captured by the two-photon microscope with ...

A new two-photon fluorescence microscope developed at UC Davis can capture high-speed images of neural activity at cellular resolution thanks to a new adaptive sampling scheme and line illumination.