Understanding the dynamics of neuronal communication is crucial for advancing neuroscience research and developing effective therapies for neurological disorders. Neuronal network models have been ...

Increasing the proximity of microelectrode arrays (MEA) to targeted neural tissues can establish efficient neural interfaces for both recording and stimulation applications. This has been achieved by ...

Neural representations arise from high-dimensional population activity, but current neuromodulation methods lack the precision to write information into the central nervous system at this complexity.

A research team has developed a nanocomposite-modified microelectrode array (MEA) that enables long-term, high-sensitivity monitoring of neuronal activity during hibernation. Their findings were ...

Carnegie Mellon University researchers have pioneered the CMU Array - a new type of microelectrode array for brain computer interface platforms. It holds the potential to transform how doctors are ...

Technological advances have led to an array of medical monitoring tools that people can use without the aid of medical professionals, like smartwatches, glucose monitors, and health tracking apps.

Aiming to transform how doctors are able to treat neurological disorders, Carnegie Mellon University collaborators pioneer the CMU Array, a customizable, 3D nano-printed, ultra-high-density ...

A KAIST research team has developed a highly stretchable microelectrode array (sMEA) designed for non-invasive electrophysiological signal measurement of organoids. The team was led by Professor ...