Nature Communications
Author:
Keywords:
Science & Technology, Multidisciplinary Sciences, Science & Technology - Other Topics, CORTICAL EXCITABILITY, MOTOR, STIMULATION, PLASTICITY, HOMEOSTASIS, Acoustic Stimulation, Adult, Behavior, Brain, Electrodes, Electroencephalography, Electromyography, Female, Humans, Learning, Male, Motor Cortex, Motor Skills, Neuronal Plasticity, Sleep, Transcranial Magnetic Stimulation, Wakefulness, Young Adult
Abstract:
It is hypothesized that deep sleep is essential for restoring the brain's capacity to learn efficiently, especially in regions heavily activated during the day. However, causal evidence in humans has been lacking due to the inability to sleep deprive one target area while keeping the natural sleep pattern intact. Here we introduce a novel approach to focally perturb deep sleep in motor cortex, and investigate the consequences on behavioural and neurophysiological markers of neuroplasticity arising from dedicated motor practice. We show that the capacity to undergo neuroplastic changes is reduced by wakefulness but restored during unperturbed sleep. This restorative process is markedly attenuated when slow waves are selectively perturbed in motor cortex, demonstrating that deep sleep is a requirement for maintaining sustainable learning efficiency.