Dynamic respiration-neural coupling in substantia nigra across sleep and anesthesia

Abstract

Respiration is increasingly recognized as a coordinator of neural activity across widespread brain regions and behavioral states. Even during sleep, respiration rhythms modulate sleep-related oscillations. While the basal ganglia are known to play roles in both sleep and respiratory regulation, their interaction with respiration rhythms remains poorly understood. Here, we examined respiration-neural couplings in the substantia nigra pars reticulata (SNr), a major output nucleus of the basal ganglia, and the primary motor cortex (M1) across multiple states in male and female mice, including non-rapid eye movement (NREM) sleep, rapid eye movement (REM) sleep, quiet wakefulness, and anesthesia. Simultaneous recordings of local field potentials (LFPs) from M1 and SNr along with diaphragm muscle activities revealed state-dependent, region specific patterns of respiration-neural coupling. Coupling strength in both SNr and M1 was attenuated during NREM sleep compared to REM sleep and quiet wakefulness. However, under ketamine/xylazine anesthesia, coupling was markedly enhanced in the SNr, but not in M1, indicating region-specific sensitivity to arousal and anesthesia state. Notably, respiration-neural coupling was systematically related to delta sub-band power; coupling strength was reduced with increased slow delta (0.5-2 Hz) and decreased fast delta (2.5-4 Hz) powers. In addition, slow delta was associated with SNr-M1 synchronization, suggesting that inter-regional communication during deep sleep may suppress respiration locking. Together, these findings highlight dynamic, state-dependent modulation of respiration-neural couplings in cortico-basal ganglia circuits, underscoring its potential role in coordinating body-brain interactions during sleep and anesthesia.

Significance Statement Neural oscillations are known to couple with respiration rhythms across various brain areas; however, this coupling in the SNr, a major output hub of the basal ganglia, remained unexplored. Current study fills this gap with several novel findings, revealing state-dependent coupling to respiration rhythms in the SNr and M1 of mice. In particular, the strength of respiration-neural coupling varied across multiple states, including NREM sleep, REM sleep, quiet wakefulness, and anesthesia, and was directly related to the delta power, a hallmark of NREM sleep. These findings provide new insight into how respiratory rhythms interact with cortico-basal ganglia circuits and demonstrate that coupling changes dynamically within and across multiple states.