A research team at Kumamoto University has developed a deep learning-based method for analyzing the cytoskeleton—the structural framework inside cells—more accurately and efficiently than ever before.

Prof. Michael Murrell's group (lead author Zachary Gao Sun, graduate student in physics) in collaboration with Prof. Garegin Papoian's group from the University of Maryland at College Park has found ...

The cytoskeleton is far more than a static scaffold—it’s a dynamic, adaptable network that shapes cells, moves cargo, and drives vital processes. From swirling cytoplasmic flows to microtubule ...

A system once tied to DNA organization in cyanobacteria has evolved into a structure that shapes the cell itself. This shift ...

Cyanobacteria—ancient microbes that oxygenated Earth and made complex life possible—are still revealing surprises billions of ...

Living cells are bombarded with molecular signals that influence their behavior. Being able to measure those signals and the response to them could help scientists learn much more about how cells work ...

Cells typically contain a cytoskeleton, which helps shuttle things around and provides structural integrity, among other functions. Microtubules are important parts of the cytoskeleton, and new ...

Unlike the rigid skeletons within our bodies, the skeletons within individual cells—cytoskeletons—are changeable, even fluid. And when these cytoskeletons reorganize themselves, they do more than ...

A research team led by Potsdam-based bioinformatician Prof. Dr Zoran Nikoloski has developed a computational approach and an accompanying tool that enables the detailed analysis and reconstruction of ...