| Literature DB >> 26812659 |
Giulio Bernardi1, Luca Cecchetti2, Francesca Siclari3, Andreas Buchmann3, Xiaoqian Yu3, Giacomo Handjaras2, Michele Bellesi3, Emiliano Ricciardi2, Steven R Kecskemeti4, Brady A Riedner3, Andrew L Alexander5, Ruth M Benca3, M Felice Ghilardi6, Pietro Pietrini7, Chiara Cirelli8, Giulio Tononi9.
Abstract
Learning leads to rapid microstructural changes in gray (GM) and white (WM) matter. Do these changes continue to accumulate if task training continues, and can they be reverted by sleep? We addressed these questions by combining structural and diffusion weighted MRI and high-density EEG in 16 subjects studied during the physiological sleep/wake cycle, after 12 h and 24 h of intense practice in two different tasks, and after post-training sleep. Compared to baseline wake, 12 h of training led to a decline in cortical mean diffusivity. The decrease became even more significant after 24 h of task practice combined with sleep deprivation. Prolonged practice also resulted in decreased ventricular volume and increased GM and WM subcortical volumes. All changes reverted after recovery sleep. Moreover, these structural alterations predicted cognitive performance at the individual level, suggesting that sleep's ability to counteract performance deficits is linked to its effects on the brain microstructure. The cellular mechanisms that account for the structural effects of sleep are unknown, but they may be linked to its role in promoting the production of cerebrospinal fluid and the decrease in synapse size and strength, as well as to its recently discovered ability to enhance the extracellular space and the clearance of brain metabolites.Entities:
Keywords: DWI; Extracellular space; MRI; Mean diffusivity; Sleep deprivation
Mesh:
Year: 2016 PMID: 26812659 PMCID: PMC4803519 DOI: 10.1016/j.neuroimage.2016.01.020
Source DB: PubMed Journal: Neuroimage ISSN: 1053-8119 Impact factor: 6.556