SLEEP MICROARCHITECTURE IN MILD COGNITIVE IMPAIRMENT: A HIGH‐DENSITY EEG STUDY

Abstract

AbstractBackgroundSleep disturbance and sleep disorders are potential risk factors for dementia. Adults with mild cognitive impairment (MCI) are at increased risk of developing dementia and many report disturbed sleep. Altered sleep neurophysiology including deficits in sleep spindles and slow wave activity (SWA) during NREM sleep have been reported in MCI, though studies are sparse. These NREM EEG oscillations are crucial for overnight memory consolidation and optimal daytime functioning. Abnormal EEG activity during sleep in MCI may adversely impact sleep‐dependent memory processes and cognitive trajectory. This study is the first to examine sleep microarchitecture using high‐density EEG technology in MCI.MethodOlder adults with multi‐domain MCI (n = 19, mean age 68.5 years) and cognitively‐intact controls (n = 22, 69 years) had 256‐channel high‐density EEG recordings during overnight polysomnography and resting wakefulness. Declarative (word paired associates) and procedural (finger tapping) memory tasks were administered before and after sleep. Neuropsychological testing and brain MRI scans were also performed. After artefact processing, spectral analysis was performed for high‐density EEG recordings. Topographical power maps were calculated for standard frequency ranges for NREM sleep (N2 and N3 (slow wave sleep)). Maps were compared between groups using normalized power (z‐scores computed for each subject).ResultThe MCI group had worse declarative (% retention, MCI vs Controls: 84.2 ± 16.6 vs. 94.5 ± 7.8, p = 0.024) and procedural (% early improvement: 92.9 ± 11.0 vs. 103.0 ± 12.0%, p = 0.017) overnight memory consolidation than the controls. Topographic analysis of high‐density EEG data revealed a regional increase in SWA (1‐4.5Hz) EEG power during N3 in a cluster of 18 electrodes overlying the centroparietal cortex in the MCI group (cluster mean t‐value = 3.11, p = 0.0036, uncorrected) and a regional reduction in SWA in the left frontal (5 channels, t = ‐3.75, p<0.001) and right temporal areas (5 channels, t = ‐3.46, p = 0.001), Figure 1.ConclusionOvernight memory consolidation was impaired in this MCI population. Regional differences in SWA during deep sleep were present in distinct brain regions and may indicate pathology. Future analysis exploring associations between EEG abnormalities with underlying brain structures may provide mechanistic insights into the impact of altered sleep neurophysiology on cognitive outcomes in MCI.