A research group conducted quantitative individual analysis on the contribution to the strength of the micrometer-scale crystallographic lamellar structures and nanometer-sized cellular structures ...

The dual-phase interpenetrating architecture was came out from the microstructure of natural materials. Based on the such unique structure, bioinspired P/CCSs was designed and fabricated via 3D ...

In a groundbreaking fusion of biology and technology, scientists have successfully 3D printed a tiny elephant inside a living cell. This remarkable feat not only showcases the potential of 3D printing ...

Custom polymer structures can now be 3D printed inside living cells using laser-based fabrication, opening paths to intracellular sensors, cell tracking tags, and embedded microlasers. (Nanowerk ...

A 3D printed ‘metamaterial’ boasting levels of strength for weight not normally seen in nature or manufacturing could change how we make everything from medical implants to aircraft or rocket parts.

RIT researchers solve multiple tissue engineering challenges by developing a novel hydrogel to host human cells and a device to 3D print bioinks safely.

Key cells in the brain, neurons, form networks by exchanging signals, enabling the brain to learn and adapt at incredible speed. Researchers have now developed a 3D-printed 'brain-like environment' ...

A new type of 3D-printed lattice structure has surprised researchers with its strength and light weight. It uses two different lattice structures merged together to eliminate the weak points normally ...

A tiny elephant establishes a new stomping ground for 3-D printing: inside cells. For the first time, scientists have 3-D printed objects within living cells, including a 10-micrometer long elephant ...