Stanford Medicine scientists investigating the neurological underpinnings of autism spectrum disorder have found that hyperactivity in a specific brain region could drive behaviors commonly associated ...

Scientists at Stanford have found that hyperactivity in the brain’s reticular thalamic nucleus may drive autism-like behaviors. In mouse models, drugs and neuromodulation techniques that suppressed ...

Scientists at EPFL’s Blue Brain Project have developed a groundbreaking computational model of the thalamic microcircuit in the mouse brain, offering new insights into the role this region plays in ...

The thalamus and thalamic reticular nucleus are situated at the heart of the mammalian brain and are known to play a key role in a wide range of functions, including the transmission of sensory ...

Proceedings of the National Academy of Sciences of the United States of America, Vol. 117, No. 23 (June 9, 2020), pp. 13066-13077 (12 pages) Layer 6 (L6) is the sole purveyor of corticothalamic (CT) ...

The thalamic reticular nucleus (TRN) is hypothesized to regulate neocortical rhythms and behavioral states. Using optogenetics and multi-electrode recording in behaving mice, we found that brief ...

Absence seizures are believed to be elicited by T-type calcium channels in the thalamic reticular nucleus of the brain that regulate influxes of calcium. These channels enable thalamic reticular ...

Researchers at Stanford Medicine have pinpointed a brain region that may drive autism-related behaviors. They report that dialing down its activity reversed symptoms in mice engineered to model autism ...

Stanford Medicine scientists investigating the neurological underpinnings of autism spectrum disorder have found that hyperactivity in a specific brain region could drive behaviors commonly associated ...

Have you ever fallen asleep desperately trying to remember something, only to wake up in the morning with the memory readily available to you? No, it’s not just you this has happened to — and nor is ...

A group of researchers has succeeded in revealing a principle mechanism of a neural network in the human brain, which will provide an important clue to potential treatments for absence seizures.