By crafting an artificial brain-like environment with microscopic nanopillars, researchers have successfully guided neurons ...

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' ...

Key cells in the brain, neurons, form networks by exchanging signals, enabling the brain to learn and adapt at incredible ...

Researchers at University of Tsukuba have discovered a novel mechanism involved in brain development. They found that small ...

Glia (light green) respond to the loss of dendrite cilia (dark pink) by accumulating excess extracellular matrix (dark green) ...

Key cells in the brain, neurons, form networks by exchanging signals, enabling the brain to learn and adapt at incredible speed.

The study was published in Advanced Functional Materials and featured on its cover. The researchers fabricated nanoscale ...

Researchers at University of Tsukuba have discovered a novel mechanism involved in brain development. They found that small fragments called micronuclei produced by neuronal nuclei are released into ...

Researchers have developed a 3D-printed model that mimics brain tissue, using nanopillar arrays to guide neuron growth. The ...

A 3D model has been developed that accurately replicates the complex structures of cerebral blood vessels, enabling ...

Key cells in the brain, neurons, form networks by exchanging signals, enabling the brain to learn and adapt at incredible speed. Researchers of the ...

Researchers have developed a 3D-printed |brain-like environment| where neurons grow similarly to a real brain.