Wearable devices like smartwatches and fitness trackers interact with parts of our bodies to measure and learn from internal processes, such as our heart rate or sleep stages. Now, MIT researchers ...

Super-resolution microscopy, or nanoscopy, enables the use of fluorescent-based molecular localization tools to study molecular structure at the nanoscale level in the intact cell. Analysis of ...

Both images show individual red blood cells. The one on the right, produced by STED, more clearly shows the Piezo1 proteins (in green), which are a mechanical calcium channel and play a crucial role ...

Although numerous spatial transcriptomics analyses exist for evaluating RNA localization, these methods face several limitations. Cell fractionation techniques, such as density gradient centrifugation ...

Subcellular structures are distinct, spatially organized physical systems within cells, encompassing membrane-bound organelles (e.g., mitochondria, endoplasmic ...

Spatial proteomics aims to reveal the locations of a group of proteins in cells or tissues to provide a spatial framework for the understanding of protein interactions or molecular mechanisms of ...

Researchers have revealed the structural underpinnings of memory formation across a broad network of neurons in the mouse brain. This work sheds light on the fundamentally flexible nature of how ...

A new advanced artificial intelligence (AI) system has shown world-leading accuracy and speed in identifying protein patterns within individual cells. The new system, developed at the University of ...