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.

Researchers have used super-resolution microscopy to unveil the geodesic mesh that supports the outer membrane of a red blood cell, in a discovery that could eventually help uncover how the malaria ...

The deep learning-based segmentation method, applied to confocal microscopy images of cortical microtubules in tobacco BY-2 cells, significantly improves density measurement accuracy compared to ...

Red blood cells must be flexible to squeeze through tiny capillaries to deliver oxygen. Chemists have now discovered the secret of this flexibility: a 2-D triangular mesh, like a geodesic dome, ...

Using physical chemistry methods to look at biology at the nanoscale, a Lawrence Berkeley National Laboratory (Berkeley Lab) researcher has invented a new technology to image single molecules with ...

Advances in multiphoton microscopy instruments and technology are leading to unique insights into the cellular world. From live-cell imaging to three dimensional reconstructions of cells and their ...

Nature has developed a unique structure as a scaffold for almost all nerve cells: the membrane-associated periodic skeleton (MPS). This specialized cytoskeletal structure is located below the cell ...

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