Imagine balancing a ruler vertically in the palm of your hand: you have to constantly pay attention to the angle of the ruler and make many small adjustments to make sure it doesn't fall over. It ...

No body, no dopamine, no problem. Scientists have successfully coached lab-grown brain tissue to solve a classic robotics challenge, proving that the will to learn is hardwired into our neurons.

Imagine balancing a ruler upright in the palm of the hand: There is a need to continually pay attention to the angle of the ruler and make several little changes to ensure it does not topple over.

Add Yahoo as a preferred source to see more of our stories on Google. Brain organoids are usually grown to mirror individual sections of the brain, and not the entire organ. Biomedical engineers have ...

A team led by Northwestern University and Shirley Ryan AbilityLab scientists have developed a new technology that can eavesdrop on the hidden electrical dialogues unfolding inside miniature, lab-grown ...

Researchers at Tianjin University and the Southern University of Science and Technology in China have created a “human-on-chip” system that combines human brain matter with a neural interface chip and ...

The Nature Index 2024 Research Leaders — previously known as Annual Tables — reveal the leading institutions and countries/territories in the natural and health sciences, according to their output in ...

Organotics, a brain organoid startup, uses AI and patient-derived brain models to fast-track personalized medicine for autism and reduce psychiatric drug failure.

Johns Hopkins University researchers have grown a novel whole-brain organoid, complete with neural tissues and rudimentary blood vessels—an advance that could usher in a new era of research into ...

Research on conditions like autism, schizophrenia and even brain cancer increasingly relies on clusters of human cells called brain organoids. These pea-size bits of neural tissue model aspects of ...

Johns Hopkins University researchers have grown a novel whole-brain organoid, complete with neural tissues and rudimentary blood vessels—an advance that could usher in a new era of research into ...