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

Infrared vibrational spectroscopy at BESSY II can be used to create high-resolution maps of molecules inside live cells and ...

Wearable or implantable devices to monitor biological activities, such as heart rate, are useful, but they are typically made ...

D cell cultures are no longer a futuristic idea. They’re already reshaping how we study diseases like cancer, offering more ...

Scientists are working to make blood cell imaging faster and more ... and size of individual cells without any dyes or contrast agents, which provides quantitative 3D information to assist diagnostic ...

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

MIT scientists have developed a new 3D human brain tissue model that could change how researchers study neurological diseases ...

New discoveries about the malaria parasite made by researchers at Columbia and Drexel universities could change the way ...

The Research Collaboratory for Structural Bioinformatics Protein Data Bank, a global scientific resource based at Rutgers ...

A new 3D human brain tissue platform developed by MIT researchers is the first to integrate all major brain cell types, including neurons, glial cells and the vasculature into a single culture.

Infrared vibrational spectroscopy at BESSY II can be used to create high-resolution maps of molecules inside live cells and cell organelles in native aqueous environment, according to a new study by a ...

When you picture a cell in your body, you probably don’t expect it to move around. Yet some cells, such as immune cells, are ...