Improvements in brain sensing technologies have allowed clinicians to perform increasingly complex surgeries and enabled researchers to map the signals of the brain that control feeling, movement, and thought.
Explore more about: Brain Disorders
he difference between a social butterfly and a lone wolf is actually at least eight differences, according to new findings by a team of Duke brain researchers.
As our brains age, small lesions begin to pop up in the bundles of white matter that carry messages between our neurons. The lesions can damage this white matter and lead to cognitive deficits. Now, researchers not only provide an explanation for the location of these lesions but also how they develop in the first place.
A team of researchers has developed a noninvasive diagnostic method that may one day replace the biopsy with a simple blood test.
NIBIB-funded engineers are using focused ultrasound to modulate motor activity in the brain without surgical device implantation, a first step toward non-invasive brain stimulation therapies.
As mice watched movies, scientists watched their brains to see how vision could be represented reliably. The answer is that consistency in representation is governed by a circuit of inhibitory neurons. Source: The Picower Institute for Learning and Memory at MIT.
NIBIB selected three winning teams for designs that excel according to four criteria: the significance of the problem being addressed; the impact on clinical care; the innovation of the design; and the ideation process or existence of a working prototype.
Compared to standard machine learning models, deep learning models are largely superior at discerning patterns and discriminative features in brain imaging, despite being more complex in their architecture.
Research into what is known as the gut-brain axis continues to reveal how the brain and gut influence each other’s health and well-being. Now researchers are endeavoring to learn more about gut-brain discourse using a model system built in a lab dish.
A new study lays out a large medical analytics framework that can be used in neuroscience and neurology to study brain connectivity in living organisms.