Japanese scientists recreate human brain circuits in lab

Researchers have created a detailed brain organoid mimicking the developing cerebral cortex, complete with blood vessels that closely resemble those in a real brain. This advance addresses a key limitation in lab-grown mini-brains, potentially allowing them to survive longer and provide deeper insights into neurological conditions. The organoid, grown from human stem cells, features evenly distributed vessels with hollow centers, marking a significant step forward in brain research.

January 12, 2026 Reported by AI

A new genetic study has identified 331 genes essential for transforming stem cells into brain cells, including a novel gene linked to neurodevelopmental disorders. Led by scientists at the Hebrew University of Jerusalem, the research highlights how early genetic disruptions can lead to conditions like autism and developmental delay. The findings, published in Nature Neuroscience, also reveal patterns in how these disorders are inherited.

Scientists are on the verge of simulating a human brain using the world's most powerful supercomputers, aiming to unlock secrets of brain function. Led by researchers at Germany's Jülich Research Centre, the project leverages the JUPITER supercomputer to model 20 billion neurons. This breakthrough could enable testing of theories on memory and drug effects that smaller models cannot achieve.

November 08, 2025 Reported by AI Fact checked

An evolutionarily ancient midbrain region, the superior colliculus, can independently carry out visual computations long attributed mainly to the cortex, according to a PLOS Biology study. The work suggests that attention-guiding mechanisms with roots more than 500 million years old help separate objects from backgrounds and highlight salient details.

Using 7‑Tesla fMRI and a placebo paradigm, University of Sydney researchers mapped how the human brainstem modulates pain by body region. The study, published in Science on August 28, 2025, outlines a somatotopic system centered on the periaqueductal gray and rostral ventromedial medulla and suggests avenues for localized, non‑opioid treatments.

January 20, 2026 Reported by AI

A new study has shown that the brain regions controlling facial expressions in macaques work together in unexpected ways, challenging prior assumptions about their division of labor. Researchers led by Geena Ianni at the University of Pennsylvania used advanced neural recordings to reveal how these gestures are encoded. The findings could pave the way for future brain-computer interfaces that decode facial signals for patients with neurological impairments.