Researchers at Carnegie Mellon University have used a nanoscale 3D printing technique that allows them to customize the microelectrode arrays used for brain computer interfaces. The approach is called ...

Figure 1. Schematic of highly stretchable MEA (sMEA) with protruding microelectrodes. On January 14th, the KAIST research team led by Professor Hyunjoo J. Lee from the School of Electrical Engineering ...

Drug development for the treatment of amyloid lateral sclerosis (ALS) requires an understanding of how genetic mutations lead to the ALS phenotype. Researchers use human induced pluripotent stem cell ...

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 ...

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 ...

Brain organoids are self-organizing tissue cultures grown from patient cell-derived induced pluripotent stem cells. They form tissue structures that resemble the brain in vivo in many ways. This makes ...

The microelectrode array with neural networks from different origins (cell line) over time: left to right shows progression from 6 days after plating to 37 days after plating on the microelectrode ...

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 ...