Rice lab pioneers an assembly kit for synthetic sense-and-respond circuits in human cells. Rice University bioengineers have ...

Using AI, Jahed, Rahmani and colleagues developed a method to correlate extracellular signals with specific intracellular signals. To develop the new method, the team first engineered an array of ...

While extracellular signals can be captured with less invasive methods, they do not provide much detail about the cell's electrical activity. "It is like listening to a conversation through a wall ...

California: A team of researchers led by the University of California, San Diego, and Stanford University has discovered a noninvasive approach for monitoring electrical activity inside cardiac ...

Researchers in the US have developed a non-invasive method to monitor the electrical activity inside heart muscle cells from the outside. Electrical signals inside heart muscle cells provide insights ...

Megakaryocytes form a three-dimensional (3D) cage composed of laminin and collagen IV connected to the basement membrane surrounding them. This microarchitecture stabilizes megakaryocytes within their ...

Comparison of methods to record signals inside cells. Current methods (left) are more costly, invasive and low-throughput. The new method (right) overcomes these hurdles by using AI to reconstruct ...

Key cells in the brain, neurons, form networks by exchanging signals, enabling the brain to learn and adapt at incredible speed. Researchers have now developed a 3D-printed 'brain-like environment' ...

The key lies in extracting the relationship between the signals inside the cells (intracellular signals) and those recorded on their surface (extracellular signals). "We discovered that ...