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Brain white matter damage and its association with neuronal synchrony during sleep

The restorative function of sleep depends partly on its ability to synchronize cerebral networks. Surprisingly, Sanchez et al. show that white matter damage secondary to traumatic brain injury is associated with higher levels of brain synchrony during sleep, implying that such damage may not impede...

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Published in:Brain (London, England : 1878) England : 1878), 2019-03, Vol.142 (3), p.674-687
Main Authors: Sanchez, Erlan, El-Khatib, Héjar, Arbour, Caroline, Bedetti, Christophe, Blais, Hélène, Marcotte, Karine, Baril, Andrée-Ann, Descoteaux, Maxime, Gilbert, Danielle, Carrier, Julie, Gosselin, Nadia
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Language:English
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Summary:The restorative function of sleep depends partly on its ability to synchronize cerebral networks. Surprisingly, Sanchez et al. show that white matter damage secondary to traumatic brain injury is associated with higher levels of brain synchrony during sleep, implying that such damage may not impede the restorative function of sleep. Abstract The restorative function of sleep partly relies on its ability to deeply synchronize cerebral networks to create large slow oscillations observable with EEG. However, whether a brain can properly synchronize and produce a restorative sleep when it undergoes massive and widespread white matter damage is unknown. Here, we answer this question by testing 23 patients with various levels of white matter damage secondary to moderate to severe traumatic brain injuries (ages 18-56; 17 males, six females, 11-39 months post-injury) and compared them to 27 healthy subjects of similar age and sex. We used MRI and diffusion tensor imaging metrics (e.g. fractional anisotropy as well as mean, axial and radial diffusivities) to characterize voxel-wise white matter damage. We measured the following slow wave characteristics for all slow waves detected in N2 and N3 sleep stages: peak-to-peak amplitude, negative-to-positive slope, negative and positive phase durations, oscillation frequency, and slow wave density. Correlation analyses were performed in traumatic brain injury and control participants separately, with age as a covariate. Contrary to our hypotheses, we found that greater white matter damage mainly over the frontal and temporal brain regions was strongly correlated with a pattern of higher neuronal synchrony characterized by slow waves of larger amplitudes and steeper negative-to-positive slopes during non-rapid eye movement sleep. The same pattern of associations with white matter damage was also observed with markers of high homeostatic sleep pressure. More specifically, higher white matter damage was associated with higher slow-wave activity power, as well as with more severe complaints of cognitive fatigue. These associations between white matter damage and sleep were found only in our traumatic brain injured participants, with no such correlation in controls. Our results suggest that, contrary to previous observations in healthy controls, white matter damage does not prevent the expected high cerebral synchrony during sleep. Moreover, our observations challenge the current line of hypotheses that white matter microstruc
ISSN:0006-8950
1460-2156
DOI:10.1093/brain/awy348