Cell cultures—single layers of cells grown in a small dish—have enabled researchers to study biological growth, develop or ...

Until today, skin, brain, and all tissues of the human body were difficult to observe in detail with an optical microscope, since the contrast in the image was hindered by the high density of their ...

Guo, Liu, and their colleagues studied the intercellular flow in a variety of biological tissues, including cells derived from pancreatic tissue. They carried out experiments in which they first ...

Scientists have uncovered a surprisingly simple “tissue code”: five rules that choreograph when, where, and how cells divide, move, and die, allowing organs like the colon to remain flawlessly ...

Similar to generative AI models that create pictures based on a photo, or a textual description of a motive, in the style of different artists, the VirtualMultiplexer produces virtual colorations for ...

Support organoid research with scalable human-based systems that enhance reproducibility and accelerate breakthroughs in biomedical science.

Dissociating tissues into single cells is a core laboratory technique and vital for widely used applications such as next-generation sequencing or flow cytometry. Scientists who employ tissue ...

Spatial maps of various tissues and organs in aging mice have revealed new insights into the aging process. Aging is a process common to many animals; however, the complexity of aging means that there ...

Microgravity offers a unique condition for tissue engineering, advancing stem cell-derived liver tissue development. But how can we transport these tissues to Earth without damaging them? Researchers ...