UBC Okanagan researchers have developed a 3D bio-printed model that closely mimics the complexity of natural lung tissue, an ...

D bioprinting uses living cells as "ink" to create functional tissues. Discover how this technology is transforming medicine ...

Magnetic micropillar arrays, made from magnetic composite materials, can change their shape under a magnetic field. However, ...

Magnetic micropillar arrays consist of tiny, vertical pin-shaped structures, arranged in a grid-like pattern. These ...

Imagine a liquid that flows freely one moment, then stiffens into a near-solid the next, and then can switch back with a ...

Here we use cryogenic electron microscopy to determine the structure of TbAQP2 from Trypanosoma brucei, bound to either the substrate glycerol or to the sleeping sickness drugs, pentamidine or ...

Bristle worms have protrusions that act like a 3D printer, helping us to understand how cells regenerate. Most people will ...

Leafcutter ants live in highly organized colonies where every ant has a job, and now researchers can flip those jobs like a switch. By manipulating just two neuropeptides, scientists can turn ...

“We pioneered protease-free sample preparation to preserve fine structure, and now, with Alpenglow, we’re entering a new era: democratizing 3D molecular imaging for the translational community.

Researchers have introduced DiffSMol, a generative AI model capable of generating realistic 3D structures of small molecules that can serve as promising drug candidates.

Plants don't just grow, they build. From towering trees to delicate flowers, complex plant shapes are sculpted with ...