Fluorescent proteins (FPs) have transformed biological imaging by enabling detailed visualisation of cellular and molecular processes in real time. Initially exemplified by the green fluorescent ...

Living organisms are made up of hundreds of thousands of cells that cooperate to create the organs and systems that breathe, eat, move, and think. Now, researchers from Japan have developed a new way ...

Fluorescent protein chromophores are the light‐emitting centres intrinsic to proteins such as green fluorescent protein (GFP) and its variants. These chromophores emerge through post‐translational ...

Quantum physics is no longer confined to cryogenic chips and vacuum chambers. It is starting to seep into the machinery of ...

Researchers at Umea University have developed a new method to directly follow viral infections in living organisms. This method can make infected cells produce fluorescent proteins, which means that ...

Researchers have developed a groundbreaking method to expand the palette of bioluminescent protein colors for cell labeling. By creating 20 distinct colors, they have enabled the simultaneous ...

A research team led by the University of Oxford's Department of Engineering Science has shown it is possible to engineer a ...

Researchers from The University of Osaka report the development of two fluorescent indicators, Gachapin and Gachapin-C, that ...

The so-called magneto-sensitive fluorescent proteins or MFPs, overcome key limitations of previous biological candidates for quantum sensors.

Protein scientists could improve reproducibility and coordination across the field by rallying around a small, shared set of "model proteins," according to a new Perspective by Connecticut College ...

20 colors of bioluminescent protein “eNLEX". The method for changing bioluminescence color (top) and the bioluminescent image of 20-color eNLEX taken with a smartphone camera (bottom). Osaka, Japan – ...