Growing tissues can crack, break, and dissociate to form structures that can later withstand immense forces.

Defect-filled lead-halide perovskites rival silicon solar cells because domain walls inside the material separate and guide charges. Researchers visualized these charge-transport networks using a ...

A study published in the journal Science Advances details a promising, new avenue toward improving awake brain mapping results by investigating the tiny, nearly imperceptible variabilities in patient ...

In laboratory experiments, researchers have produced ear cartilage that remains form-stable in animal models. Only one ...

In a year of tight margins and rising input costs, Maryland farmer Tom Linthicum has found a way to make every dollar count. By fine-tuning his approach to nitrogen use, he’s not only saving money, ...

Holi celebrations feel incomplete without a plate of soft, chilled dahi bhalla topped with sweet and tangy chutneys. If ...

A multidisciplinary team have built hydrogels built entirely from synthetic peptides so their properties can be precisely ...

With a new mathematical model, a team of biophysicists has revealed fresh insights into how biological tissues are shaped by the active motion of structural imperfections known as "topological defects ...

Research indicates that uniform materials could be the culprit of deadly infections that can occur when using synthetic materials for cardiovascular grafts.

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

The discovery that tissues use electricity to expel unhealthy cells is part of a surge of renewed interest in the currents flowing through our bodies. We’re used to thinking of the brain as an ...