Basal ganglia-independent thalamic bursts do not wake cortex during sleep

The thalamus is a key forebrain structure that gates peripheral, subcortical, and cortico-cortical communication ^1,2 . Awake thalamic bursts provide the cortex with a “wake-up” signal ^2–4 . Paradoxically, thalamic neurons discharge tonically during cellular depolarization and activated brain states (wakefulness, REM sleep) but burst during hyperpolarization and NREM sleep ^5–9 . It has been proposed that NREM thalamic bursts do not awaken the cortex because of their periodic and synchronized nature ^2–4 ; however, this has never been tested in vivo during natural sleep. We simultaneously recorded polysomnographic signals, local field potentials, and spiking activity from multiple thalamic neurons in the ventral anterior and centromedian nuclei of two female non-human primates during naturally occurring vigilance states. These nuclei receive GABAergic output from the basal ganglia ^10,11 , with discharge rate and GABA outflow decreasing during NREM sleep ¹² . We found that despite the expected thalamic depolarization, bursting increased significantly. NREM bursts were neither periodic nor highly synchronized. However, EEG activity time-locked to burst onset during NREM sleep differed markedly from that observed during wakefulness and REM sleep. These results support a modulatory, rather than a driving, relationship between the basal ganglia and thalamus. NREM thalamic bursts do not awaken the cortex, probably due to unique state-dependent thalamocortical dynamics.