Investigation of Slow-wave Activity Saturation during Surgical Anesthesia Reveals a Signature of Neural Inertia in Humans

Abstract Background Previously, we showed experimentally that saturation of slow-wave activity provides a potentially individualized neurophysiologic endpoint for perception loss during anesthesia. Furthermore, it is clear that induction and emergence from anesthesia are not symmetrically reversible processes. The observed hysteresis is potentially underpinned by a neural inertia mechanism as proposed in animal studies. Methods In an advanced secondary analysis of 393 individual electroencephalographic data sets, we used slow-wave activity dose-response relationships to parameterize slow-wave activity saturation during induction and emergence from surgical anesthesia. We determined whether neural inertia exists in humans by comparing slow-wave activity dose responses on induction and emergence. Results Slow-wave activity saturation occurs for different anesthetics and when opioids and muscle relaxants are used during surgery. There was wide interpatient variability in the hypnotic concentrations required to achieve slow-wave activity saturation. Age negatively correlated with power at slow-wave activity saturation. On emergence, we observed abrupt decreases in slow-wave activity dose responses coincident with recovery of behavioral responsiveness in ~33% individuals. These patients are more likely to have lower power at slow-wave activity saturation, be older, and suffer from short-term confusion on emergence. Conclusions Slow-wave activity saturation during surgical anesthesia implies that large variability in dosing is required to achieve a targeted potential loss of perception in individual patients. A signature for neural inertia in humans is the maintenance of slow-wave activity even in the presence of very-low hypnotic concentrations during emergence from anesthesia.

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EEG delta power and auditory arousal in rested and sleep-deprived rabbits

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1997.272.2.r648 ◽

1997 ◽

Vol 272 (2) ◽

pp. R648-R655 ◽

Cited By ~ 4

Author(s):

M. R. Opp ◽

L. A. Toth ◽

E. A. Tolley

Keyword(s):

Slow Wave ◽

Slow Wave Sleep ◽

Rabbit Model ◽

Stimulus Presentation ◽

Wave Activity ◽

Slow Wave Activity ◽

Auditory Stimuli ◽

Delta Power ◽

Postural Changes ◽

Behavioral Responsiveness

Slow-wave activity in the electroencephalogram is thought to reflect the depth or intensity of sleep. This hypothesis is primarily derived from studies of rats or humans. However, some characteristics of sleep of rabbits differ from those of rats or humans. To determine whether slow-wave activity (power density in the delta frequency band of 0.5-5.0 Hz) correlates with arousability in rabbits, we presented auditory stimuli (72-90 dB) to control or sleep-deprived animals during slow-wave sleep. The resulting behavioral responses, defined by changes in eye state and body posture, and the latency to return to sleep were used as measures of arousability. Behavioral responsiveness to auditory stimuli increased with increasing stimulus intensity in both control and sleep-deprived animals. Overall, however, sleep-deprived animals exhibited fewer postural changes and eye openings than did control rabbits. Sleep-deprived rabbits also more rapidly returned to sleep after the stimulus presentation than did control animals. Latency to return to sleep was correlated with delta power before stimulus presentation, but behavioral responsiveness was not. These data suggest that, in this rabbit model, delta power may not be predictive of behavioral arousability but may reflect sleep propensity.

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Visual imagery and visual perception induce similar changes in occipital slow waves of sleep

Journal of Neurophysiology ◽

10.1152/jn.00085.2019 ◽

2019 ◽

Vol 121 (6) ◽

pp. 2140-2152 ◽

Cited By ~ 6

Author(s):

Giulio Bernardi ◽

Monica Betta ◽

Jacinthe Cataldi ◽

Andrea Leo ◽

José Haba-Rubio ◽

...

Keyword(s):

Visual Perception ◽

Eye Movement ◽

Slow Wave ◽

Visual Imagery ◽

Nrem Sleep ◽

Wave Activity ◽

Slow Waves ◽

Slow Wave Activity ◽

Short Term ◽

Visual Areas

Previous studies have shown that regional slow-wave activity (SWA) during non-rapid eye movement (NREM) sleep is modulated by prior experience and learning. Although this effect has been convincingly demonstrated for the sensorimotor domain, attempts to extend these findings to the visual system have provided mixed results. In this study we asked whether depriving subjects of external visual stimuli during daytime would lead to regional changes in slow waves during sleep and whether the degree of “internal visual stimulation” (spontaneous imagery) would influence such changes. In two 8-h sessions spaced 1 wk apart, 12 healthy volunteers either were blindfolded while listening to audiobooks or watched movies (control condition), after which their sleep was recorded with high-density EEG. We found that during NREM sleep, the number of small, local slow waves in the occipital cortex decreased after listening with blindfolding relative to movie watching in a way that depended on the degree of visual imagery subjects reported during blindfolding: subjects with low visual imagery showed a significant reduction of occipital sleep slow waves, whereas those who reported a high degree of visual imagery did not. We also found a positive relationship between the reliance on visual imagery during blindfolding and audiobook listening and the degree of correlation in sleep SWA between visual areas and language-related areas. These preliminary results demonstrate that short-term alterations in visual experience may trigger slow-wave changes in cortical visual areas. Furthermore, they suggest that plasticity-related EEG changes during sleep may reflect externally induced (“bottom up”) visual experiences, as well as internally generated (“top down”) processes.NEW & NOTEWORTHY Previous work has shown that slow-wave activity, a marker of sleep depth, is linked to neural plasticity in the sensorimotor cortex. We show that after short-term visual deprivation, subjects who reported little visual imagery had a reduced incidence of occipital slow waves. This effect was absent in subjects who reported strong spontaneous visual imagery. These findings suggest that visual imagery may “substitute” for visual perception and induce similar changes in non-rapid eye movement slow waves.

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Sa1640 NONINVASIVE MEASUREMENT OF SMALL BOWEL SLOW WAVE ACTIVITY IN NEONATES - A PILOT STUDY

Gastroenterology ◽

10.1016/s0016-5085(20)31606-1 ◽

2020 ◽

Vol 158 (6) ◽

pp. S-364

Author(s):

Suseela Somarajan ◽

Nicole D. Muszynski ◽

Aurelia s. Monk ◽

Joseph D. Olson ◽

Alexandra Russell ◽

...

Keyword(s):

Pilot Study ◽

Small Bowel ◽

Slow Wave ◽

Wave Activity ◽

Slow Wave Activity ◽

Noninvasive Measurement

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Slow Wave Activity Related to Working Memory Maintenance in the N-Back Task

Journal of Psychophysiology ◽

10.1027/0269-8803/a000164 ◽

2016 ◽

Vol 30 (4) ◽

pp. 141-154 ◽

Cited By ~ 7

Author(s):

Kira Bailey ◽

Gregory Mlynarczyk ◽

Robert West

Keyword(s):

Working Memory ◽

Slow Wave ◽

Time Course ◽

Relevant Information ◽

Wave Activity ◽

Slow Wave Activity ◽

Response Accuracy ◽

Functional Neuroanatomy ◽

Stimulus Interval ◽

Back Task

Abstract. Working memory supports our ability to maintain goal-relevant information that guides cognition in the face of distraction or competing tasks. The N-back task has been widely used in cognitive neuroscience to examine the functional neuroanatomy of working memory. Fewer studies have capitalized on the temporal resolution of event-related brain potentials (ERPs) to examine the time course of neural activity in the N-back task. The primary goal of the current study was to characterize slow wave activity observed in the response-to-stimulus interval in the N-back task that may be related to maintenance of information between trials in the task. In three experiments, we examined the effects of N-back load, interference, and response accuracy on the amplitude of the P3b following stimulus onset and slow wave activity elicited in the response-to-stimulus interval. Consistent with previous research, the amplitude of the P3b decreased as N-back load increased. Slow wave activity over the frontal and posterior regions of the scalp was sensitive to N-back load and was insensitive to interference or response accuracy. Together these findings lead to the suggestion that slow wave activity observed in the response-to-stimulus interval is related to the maintenance of information between trials in the 1-back task.

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