A Jacobs School researcher is focused on learning more about how tight junctions form naturally — and how their breakdown can lead to disease.

In this webinar, Brian Haldeman will discuss how Leprechaun enables complete biophysical characterization of in-process or ...

Led by biomedical engineer Vadim Backman, the study reveals that DNA’s 3D physical structure holds a “geometric code” — a ...

Lateone monsoon evening in Tiruppur, a textile buyer ran two fingers across a swatch he couldn’t quite place. It felt like ...

Artificial intelligence is getting really good at helping doctors diagnose problems and even discover new drugs faster. It ...

MIT researchers discovered that the genome’s 3D structure doesn’t vanish during cell division as previously thought. Instead, ...

The Korea Research Institute of Standards and Science (KRISS) has developed an artificial intelligence (AI)-based image ...

Future surgeries might include a robotic 3D printer restoring body tissue, perfecting reconstructive procedures, or building ...

The neurons in our brain that underlie thought connect to each other using tiny branch-like structures on their surfaces ...

Standard laboratory tests can fail to detect many disease-causing DNA changes. Now, a novel 3D chromosome mapping method can ...

Ribosomes are the cell's protein factories, which read the genetic code and assemble the proteins that every organism needs to live. But as far as how ribosomes themselves were formed, tantalizingly ...

Spheroids and organoids, two examples of 3D cell culture models, have become invaluable tools to study the processes that dictate behavior of tissues under physiological and pathological conditions, ...