A classical way to image nanoscale structures in cells is with high-powered, expensive super-resolution microscopes. As an alternative, MIT researchers have developed a way to expand tissue before ...

A classical way to image nanoscale structures in cells is with high-powered, expensive super-resolution microscopes. As an alternative, MIT researchers have developed a single-step technique for ...

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 ...

Our brain is a complex organ. Billions of nerve cells are wired in an intricate network, constantly processing signals, enabling us to recall memories or to move our bodies. Making sense of this ...

Researchers have developed a new microscopy technology called decrowding expansion pathology (dExPath) to analyze brain tissue. By pulling proteins apart with dExPath, researchers can stain proteins ...

This cutting-edge AI method transforms microscopy, delivering clear images of thick samples without the need for costly ...

Researchers developed a large-scale, dynamic imaging technique using mesoscopic oblique plane microscopy, which can capture 3D images of entire organisms and maintain cellular resolution. A new ...

A scanning electron microscope reveals nematodes (highlighted in green) inside the spongy mesophyll of a European beech (Fagus sylvatica) leaf infected with beech leaf disease (BLD). Eggs are marked ...