The funding, part of a new ARPA-H bioprinting initiative, aims to create transplant-ready organs—potentially within ...

3D bioprinting combines cells, growth factors, and biomaterials to fabricate biomedical parts. The process requires special “bio-inks,” often made of materials like alginate or gelatin. A key goal is ...

The study shows that fat tissue, when processed and cultured in a specific way, can self-organize into structures resembling ...

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

A recent study published in Engineering has unveiled a novel approach to generating functional organoids from human adult adipose tissue.

Discover how human adipose tissue can be transformed into functional organoids representing all three germ layers—mesoderm, ...

A simple light-based method is uncovering hidden fiber networks inside the brain and body, even in tissue slides over 100 years old.

Forming sensory organs requires complicated interactions between numerous cell types. Building these tissues in a dish from human stem cells helps researchers understand how they develop over time and ...

Breakthroughs, discoveries, and DIY tips sent every weekday. Terms of Service and Privacy Policy. Budding surgeons may soon train on stretchy, lifelike 3D-printed ...

Perhaps our most defining characteristic as a species, the six-layered human cortex, hosts billions of neural connections that bestow Homo sapiens with higher-order thinking. But how does this ...