Imagine predicting the exact finishing order of the Kentucky Derby from a still photograph taken 10 seconds into the race. That challenge pales in comparison to what researchers face when trying to ...

Understanding temporal dynamics in tissue biology is key to linking transcriptomic snapshots to physiological function.

In a new study published in Nature Chemistry, UNC-Chapel Hill researcher Ronit Freeman and her colleagues describe the steps they took to manipulate DNA and proteins - essential building blocks of ...

Innovative and cutting-edge technology transforms functional live-cell analysis by enabling precise, flexible, and scalable end-to-end immuno-oncology, antibody, and cell therapy discovery.

A new study by scientists at the University of North Carolina at Chapel Hill reveals that the cells shaping our organs may be far more mobile and coordinated than once believed. The study is published ...

Every time a eukaryotic cell divides, it faces a monumental challenge: It must carefully duplicate and divide its genetic ...

For decades, scientists have known that bacteria can exchange genetic material, in a process called horizontal gene transfer.

The adult mammalian heart bears limited regenerative capacity, resulting in the irreversible loss of cardiomyocytes post-cardiac injury, and often culminating in end-stage heart failure. Cardiomyocyte ...

Researchers generated the most comprehensive single-nucleus transcriptomic atlas of pig intestines to date, covering wild boars and domestic pigs across four key postnatal developmental stages. The ...