Sleep-wake states change the interictal localization of candidate epileptic source generators

Study Objectives To compare estimated epileptic source localizations from 5 sleep-wake states (SWS): wakefulness (W), rapid eye movement sleep (REM), and non-REM 1-3. Methods Electrical source localization (sLORETA) of interictal spikes from different SWS on surface EEG from the epilepsy monitoring unit at spike peak and take-off, with results mapped to individual brain models for 75% of patients. Concordance was defined as source localization voxels shared between 2-5 SWS, and discordance as those unique to 1 SWS against 1-4 other SWS. Results 563 spikes from 16 prospectively recruited focal epilepsy patients across 161 day-nights. SWS exerted significant differences at spike peak but not take-off. Source localization size did not vary between SWS. REM localizations were smaller in multifocal than unifocal patients (28.8% vs. 54.4%, p=0.0091). All 5 SWS contributed about 45% of their localizations to converge onto 17.0 +/- 15.5% voxels. Against any one other SWS, REM was least concordant (54.4% vs. 66.9%, p=0.0006) and most discordant (39.3% vs. 29.6%, p=0.0008). REM also yielded the most unique localizations (20.0% vs. 8.6%, p=0.0059). Conclusions REM was best suited to identify candidate epileptic sources. sLORETA proposes a model in which an omni-concordant core of source localizations shared by all 5 SWS is surrounded by a penumbra of source localizations shared by some but not all SWS. Uniquely, REM spares this core to move source voxels from the penumbra to unique cortex not localized by other SWS. This may reflect differential intra-spike propagation in REM, which may account for its reported superior localizing abilities.

Automated summary

This study compared epileptic source localizations from different sleep-wake states and found that REM sleep is best suited for identifying potential epileptic sources.