Modern biomedical research depends on the ability to see what is happening inside biological tissue. Among the available ...

A new imaging device using Raman Spectral Projection Tomography offers non-destructive, detailed views of deep tissue structures. Developed by researchers from King’s College London, the University of ...

Hidden inside every organ, microscopic fibers form a scaffolding that quietly shapes how we move, think, and heal. For the first time, scientists have produced detailed maps of these fiber webs across ...

Researchers developed bioengineered lymphatic tissue that replaced missing lymph nodes in mice, with potential to treat lymphedema.

Advancements in spatial proteomics enable detailed tissue mapping, linking protein localization to disease mechanisms and ...

Every day, your body replaces billions of cells – and yet, your tissues stay perfectly organized. How is that possible? A team of researchers at ChristianaCare’s Helen F. Graham Cancer Center & ...

Every day, your body replaces billions of cells-and yet, your tissues stay perfectly organized. How is that possible? A team of researchers at ChristianaCare's Helen F. Graham Cancer Center & Research ...

Under the surface of an organ, many different cell types participate in crucial interactions. This means that when an organ suffers damage, fixing it is not as easy as slapping on a Band-Aid.

This review innovatively proposes the use of electrospinning to fabricate electroactive fibrous scaffolds, which mimic the structure of the extracellular matrix while providing electrical activity, ...