Hidden inside every organ, microscopic fibers form a scaffolding that quietly shapes how we move, think, and heal. For the ...

Obtaining clearer and more detailed microscopic images deep within tissue has become a rich area of research in fields ranging from adaptive optics to photodynamic therapy. Visualising biological ...

Researchers at TU Graz have proven that espresso is a favourable alternative to the highly toxic and radioactive uranyl acetate in the analysis of biological samples.

A new holographic microscope allows scientists to see through the skull and image the brain. The new label-free deep-tissue imaging with the wave correction algorithm retrieves the fine neural network ...

During image analysis, researchers use light sheet microscopy of cleared tissue as a preferred method for high throughput volumetric imaging. A flexible system can provide a range of sizes, resolution ...

To ensure that the tissue structures of biological samples are easily recognizable under the electron microscope, they are ...

With the advancement of artificial intelligence (AI), researchers are using AI techniques to improve pathology workflow. A recent study from the University of California Los Angeles (UCLA) used deep ...

The researchers demonstrated the utility of their technique on a slice of a mouse brain, 200 microns (0.2 millimeters) in thickness. First, they made their tissue sample see-through using a tweaked ...

Encouraged by these results, Dudin, Dey, Guichard, and Hamel launched a close collaboration. Three years later, their work has produced near-encyclopedic insight into hundreds of protist species and ...

Researchers at Graz University of Technology found that ordinary espresso can replace toxic uranyl acetate for electron ...