A new bioengineered neuronal circuit board "BioConNet" allows scientists to artificially engineer human brain-like wiring at ...

Lab-grown mini-brains learned to play video games using electrical signals, improving from 4.5% to 46% success in AI balance ...

Neurons placed inside engineered living bodies built from frog cells self-organize, become active, and reshape movement ...

In a recent study published in Cell Stem Cell, researchers produced three-dimensional (3D) bioprinted human brain tissues, allowing for the creation of functioning neural networks that could simulate ...

Lab-grown brain tissue learned to balance a virtual pole with 46% accuracy, revealing how living neural networks adapt and ...

A new 3D electronic mesh device allows scientists to record and stimulate activity across almost the entire surface of ...

Precise electrical stimulation is essential for modern neural interfaces, but unwanted current spread often activates off-target cells and limits resolution. A new microneedle electrode design ...

Talk about thinking small: researchers at Harvard University have devised a new way to implant flexible bioelectronic devices in the embryos of frogs, mice, and lizards, enabling them to monitor brain ...

The comparison underscores a paradox at the heart of modern AI development: today’s neural networks are inspired by the brain ...