RESUMEN
Microglia, the resident immune cells in the brain, dynamically adapt their morphology based on their functional state. This study explored the relationship between microglial morphology and sleep-wake cycles in mice. Using Iba1 immunostaining to identify microglia, we quantified morphological changes in microglia at different timepoints in multiple brain regions (cortex, hippocampus, basal forebrain, hindbrain, and cerebellum) in B6 male mice using semi-automated 3D structural analysis. Simultaneously, in a separate group, we monitored wake and sleep stage-specific brain activity using EEG/EMG recordings. During natural sleep-wake cycles, we observed increased microglial complexity (enlarged volume, territorial coverage, and ramification) during wakefulness, characterized by high-frequency theta (8-12 Hz) and gamma activity (30-80 Hz). Conversely, during NREM sleep, which is dominated by delta activity (0.5-4 Hz), microglia displayed reduced complexity. Notably, this pattern was absent in brain regions lacking direct functional connections to areas generating vigilance stage-dependent thalamocortical oscillations. We then extended wakefulness to decouple circadian influence from sleep-wake-specific neuronal activity. This procedure attenuated the decrease in microglial complexity observed during natural sleep, suggesting a crucial role for neuronal activity. Subsequent recovery sleep restored microglial features, independent of the time of day (zeitgeber time). These findings reveal a dynamic interplay between vigilance stage-specific thalamocortical activity and microglial morphology across various brain regions. This suggests a potential role for microglia in sleep regulation and warrants further investigation to understand the underlying mechanisms.
RESUMEN
Primary head injury is often followed by secondary brain damage. However, the association between injury circumstances and the prevalence of secondary injuries remains unclear. We report the prevalence and association of secondary brain injuries with the circumstances in which a head injury was sustained. The sample comprised 76 neuropathologically examined medico-legal autopsy cases with an acute primary head injury. Neuropathology reports were analysed to determine the prevalence of various secondary injuries, i.e., hypoxic-ischaemic neuronal injury, brain oedema, and vascular axonal injury (VAI). The prevalences were compared between cases from three distinct injury circumstances, i.e., fall, assault, and strangulation. The sample had a median age of 49 years (interquartile range 27-73) and 71.1% were identified as male. As for distinct injury circumstances, the sample comprised 14 fall cases, 21 assault victims, and 6 strangulation victims. The prevalence of hypoxic-ischaemic neuronal injury was highest in strangulations (100.0%), followed by assaults (81.0%) and falls (64.3%); of specific brain regions, statistically significant differences between the three case groups were found in frontal and parietal cortex (p ≤ 0.018) and the hippocampus (p = 0.005). Brain oedema was present in approximately half of assault (47.6%) and strangulation cases (50.0%), contrastingly to the lower prevalence in falls (7.1%; p = 0.024). The prevalence of VAI appeared higher among assault (23.8%) and strangulation cases (16.7%) compared to falls (7.1%), but the differences were not statistically significant. We conclude that hypoxic-ischaemic neuronal injury and brain oedema were more prevalent among assault and strangulation cases compared to falls.