A team of researchers at the University of California, San Francisco (UCSF) has applied relatively simple tissue modeling and cell patterning techniques to generate highly precise 3D shapes, including ...

The complex 3D shapes of brains, lungs, eyes, hands, and other vital bodily structures emerge from the way in which flat 2D sheets of cells fold during embryonic development. Now, researchers at ...

Many of the complex folded shapes that form mammalian tissues can be recreated with very simple instructions, UC San Francisco bioengineers report December 28 in the journal Developmental Cell. By ...

Scientists have now discovered a key feature of embryonic tissue that helps explain how this process is carried out so faithfully each time. In a study of fruit flies, they found that the ...

We usually assume that tissue folding (the process that creates organs, embryos, and the deep ridges of the human brain) requires complex internal control. So then how does one of the world’s simplest ...

Mechanical tension between tethered cells cues developing tissues to fold. Researchers can now program synthetic tissue to make coils, cubes and rippling plates. When it comes to tissue engineering, ...

University of Delaware materials scientist Xinqiao Jia has received a combined $4.85 million in funding from the National Institutes of Health (NIH) for research aimed at improving human health ...