Scientists from the University of Wisconsin-Madison have successfully replicated some of the restorative effects of deep sleep in awake mice by artificially inducing slow-wave brain activity. Using optogenetics to control specific neurons, researchers triggered localized cortical activity that mimics the NREM sleep phase responsible for synaptic homeostasis and the reorganization of neural connections. This targeted stimulation significantly reduced signs of fatigue and improved memory retention and cognitive performance in the mice following prolonged wakefulness. While the researchers caution that this technique is not a substitute for natural sleep, the findings suggest that localized neural stimulation can effectively preserve brain function during extended periods of wakefulness. Future research aims to explore whether similar cognitive benefits can be achieved in humans through non-invasive methods, such as transcranial electrical stimulation.
NIH-funded study in animals offers new details about how the brain resets during sleep.
By inducing specific patterns of activity in small portions of the brain in awake mice, researchers supported by the National Institutes of Health (NIH) have triggered a recalibration of neural connections that normally only occurs during sleep. This new approach offset the effects of sleep deprivation in memory tasks and revealed features of sleep that are key to its restorative effect.
“What we’re essentially doing is forcing sleep in a local region of the brain. While that part is solidifying memories and restoring learning capacity, other parts stay aware/vigilant and connected to environment,” said corresponding author Chiara Cirelli, M.D., Ph.D., a professor of psychiatry at the University of Wisconsin-Madison. “Dolphins do something similar, sleeping with only one brain hemisphere at a time.”
