Physiological basis: how NREM sleep components can promote and REM sleep components can suppress seizure discharge propagation

Objectives: To describe how the neural generators of different sleep compon ents can provoke seizure discharge propagation during NREM sleep and can su ppress it during REM sleep. Methods: Experimental manipulations of discrete physiological components we re conducted in feline epilepsy models (n = 64), mostly in the systemic pen icillin epilepsy model of primary generalized epilepsy and the amygdala kin dling model of the localization-related seizure disorder, temporal lobe epi lepsy. Procedures included seizure induction as well as quantifying norepin ephrine concentrations (microdialysis) and the sleep-waking state distribut ion of seizures before and after lesions, systemic and localized drug admin istration and/or photic stimulation. Results: (1) Neural generators of synchronous EEG oscillations, including t onic background slow waves and phasic 'arousal' events (sleep EEG transient s such as sleep spindles, k-complexes), can combine to promote electrograph ic seizure propagation during NREM and drowsiness; anti-gravity muscle tone permits seizure-related movement. (2) Neural generators of asynchronous ne uronal discharge patterns can reduce electrographic seizures during alert w aking and REM sleep; skeletal motor paralysis blocks seizure-related moveme nt during REM. (3) Etiology of the seizure disorder can interact with sleep and arousal mechanisms to determine sleep-waking state distribution of int erictal and ictal events. Conclusions: Differential effects of NREM versus REM sleep components on se izure discharge propagation are to some extent non-specific and in other wa ys specific to seizure etiology. (C) 2000 Elsevier Science Ireland Ltd. All rights reserved.