Abstract
During the transition from neonate to adulthood, brain maturation establishes coherence between behavioral states—wakefulness, non-rapid eye movement, and rapid eye movement sleep. Few studies have characterized and analyzed cerebral rhythms and the sleep–wake cycle in early ages, in relation to adulthood. Since the analysis of sleep in early ages can be used as a predictive model of brain development and the subsequent emergence of neural disturbances in adults, we performed a study on late neonatal and adult wild-type C57BL/6 mice. We acquired longitudinal 24 h electroencephalogram and electromyogram recordings and performed time and spectral analyses. We compared both age groups and found that late neonates: (i) spent more time in wakefulness and less time in non-rapid eye movement sleep, (ii) showed an increased relative band power in delta, which, however, reduced in theta during each behavioral state, (iii) showed a reduced relative band power in beta during wakefulness and non-rapid eye movement sleep, and (iv) manifested an increased total power over all frequencies. Given the mice–human age equivalence, the data presented here might have implications for the clinical context in the analysis of electroencephalogram and sleep-based early and late diagnosis after injury or neurodegeneration.
Highlights
Sleep is a state of cerebral activity that is regulated by different brain structures, including the hypothalamus, brain stem, and basal ganglia
We found that neonatal mice spent more time in wakefulness than in non-rapid eye movement (NREM) sleep during the 12 h-light phase, while adult mice did not (Figure 2A vs. Figure 3A)
We found brain maturation signs associated with the EEG relative power within the 0–35 Hz. frequencies for each behavioral state during the 12 h-light and 12 h-dark phases (Figure 4A)
Summary
Sleep is a state of cerebral activity that is regulated by different brain structures, including the hypothalamus, brain stem, and basal ganglia. The time and depth of sleep is influenced by the circadian rhythm and the duration of previous wakefulness. The sleep– wake cycle is controlled by the suprachiasmatic nuclei (SCN) of the hypothalamus, which aligns a central circadian clock with the light/dark cycle [1]. Studies in rodents have shown that sleep facilitates neural maturation and prevents apoptosis in developing brains [4,5]. Brain maturation establishes coherence between behavioral states—wakefulness, non-rapid eye movement (NREM), and rapid eye movement (REM) sleep. The time spent in REM sleep slowly decreases, while time spent in wakefulness and NREM sleep increases [2,6,7]
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