AUTHOR=Jones Keith G. , Lybbert Carter , Euler Matthew J. , Huang Jason , Lunt Seth , Richards Sindhu V. , Jessop Jacob E. , Larson Adam , Odell David H. , Kuck Kai , Tadler Scott C. , Mickey Brian J. TITLE=Diversity of electroencephalographic patterns during propofol-induced burst suppression JOURNAL=Frontiers in Systems Neuroscience VOLUME=17 YEAR=2023 URL=https://www.frontiersin.org/journals/systems-neuroscience/articles/10.3389/fnsys.2023.1172856 DOI=10.3389/fnsys.2023.1172856 ISSN=1662-5137 ABSTRACT=
Burst suppression is a brain state consisting of high-amplitude electrical activity alternating with periods of quieter suppression that can be brought about by disease or by certain anesthetics. Although burst suppression has been studied for decades, few studies have investigated the diverse manifestations of this state within and between human subjects. As part of a clinical trial examining the antidepressant effects of propofol, we gathered burst suppression electroencephalographic (EEG) data from 114 propofol infusions across 21 human subjects with treatment-resistant depression. This data was examined with the objective of describing and quantifying electrical signal diversity. We observed three types of EEG burst activity: canonical broadband bursts (as frequently described in the literature), spindles (narrow-band oscillations reminiscent of sleep spindles), and a new feature that we call low-frequency bursts (LFBs), which are brief deflections of mainly sub-3-Hz power. These three features were distinct in both the time and frequency domains and their occurrence differed significantly across subjects, with some subjects showing many LFBs or spindles and others showing very few. Spectral-power makeup of each feature was also significantly different across subjects. In a subset of nine participants with high-density EEG recordings, we noted that each feature had a unique spatial pattern of amplitude and polarity when measured across the scalp. Finally, we observed that the Bispectral Index Monitor, a commonly used clinical EEG monitor, does not account for the diversity of EEG features when processing the burst suppression state. Overall, this study describes and quantifies variation in the burst suppression EEG state across subjects and repeated infusions of propofol. These findings have implications for the understanding of brain activity under anesthesia and for individualized dosing of anesthetic drugs.