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Tracking the Sleep Onset Process: An Empirical Model of Behavioral and Physiological Dynamics
- Source :
- PLoS Computational Biology, Vol 10, Iss 10, p e1003866 (2014), PLoS Computational Biology
- Publication Year :
- 2014
- Publisher :
- Public Library of Science (PLoS), 2014.
-
Abstract
- The sleep onset process (SOP) is a dynamic process correlated with a multitude of behavioral and physiological markers. A principled analysis of the SOP can serve as a foundation for answering questions of fundamental importance in basic neuroscience and sleep medicine. Unfortunately, current methods for analyzing the SOP fail to account for the overwhelming evidence that the wake/sleep transition is governed by continuous, dynamic physiological processes. Instead, current practices coarsely discretize sleep both in terms of state, where it is viewed as a binary (wake or sleep) process, and in time, where it is viewed as a single time point derived from subjectively scored stages in 30-second epochs, effectively eliminating SOP dynamics from the analysis. These methods also fail to integrate information from both behavioral and physiological data. It is thus imperative to resolve the mismatch between the physiological evidence and analysis methodologies. In this paper, we develop a statistically and physiologically principled dynamic framework and empirical SOP model, combining simultaneously-recorded physiological measurements with behavioral data from a novel breathing task requiring no arousing external sensory stimuli. We fit the model using data from healthy subjects, and estimate the instantaneous probability that a subject is awake during the SOP. The model successfully tracked physiological and behavioral dynamics for individual nights, and significantly outperformed the instantaneous transition models implicit in clinical definitions of sleep onset. Our framework also provides a principled means for cross-subject data alignment as a function of wake probability, allowing us to characterize and compare SOP dynamics across different populations. This analysis enabled us to quantitatively compare the EEG of subjects showing reduced alpha power with the remaining subjects at identical response probabilities. Thus, by incorporating both physiological and behavioral dynamics into our model framework, the dynamics of our analyses can finally match those observed during the SOP.<br />Author Summary How can we tell when someone has fallen asleep? Understanding the way we fall asleep is an important problem in sleep medicine, since sleep disorders can disrupt the process of falling asleep. In the case of insomnia, subjects may fall asleep too slowly, whereas during sleep deprivation or narcolepsy, subjects fall asleep too quickly. Current methods for tracking the wake/sleep transition are time-consuming, subjective, and simplify the sleep onset process in a way that severely limits the accuracy, power, and scope of any resulting clinical metrics. In this paper, we describe a new physiologically principled method that dynamically combines information from brainwaves, muscle activity, and a novel minimally-disruptive behavioral task, to automatically create a continuous dynamic characterization of a person's state of wakefulness. We apply this method to a cohort of healthy subjects, successfully tracking the changes in wakefulness as the subjects fall asleep. This analysis reveals and statistically quantifies a subset of subjects who still respond to behavioral stimuli even though their brain would appear to be asleep by clinical measures. By developing an automated tool to precisely track the wake/sleep transition, we can better characterize and diagnose sleep disorders, and more precisely measure the effect of sleep medications.
- Subjects :
- Male
Physiology
Computer science
Electroencephalography
computer.software_genre
Sleep medicine
Mathematical and Statistical Techniques
Task Performance and Analysis
Medicine and Health Sciences
lcsh:QH301-705.5
Ecology
medicine.diagnostic_test
3. Good health
Computational Theory and Mathematics
Modeling and Simulation
Physical Sciences
Probability distribution
Female
Sleep (system call)
Sleep onset
Statistics (Mathematics)
Bayesian Statistics
Research Article
Adult
medicine.medical_specialty
animal structures
Process (engineering)
Research and Analysis Methods
Machine learning
Models, Biological
Young Adult
Cellular and Molecular Neuroscience
Data structure alignment
Genetics
medicine
Humans
Wakefulness
Statistical Methods
Time point
Molecular Biology
Ecology, Evolution, Behavior and Systematics
Simulation
Computational Neuroscience
business.industry
Computational Biology
Biology and Life Sciences
lcsh:Biology (General)
Artificial intelligence
Sleep
Physiological Processes
business
computer
Mathematics
Neuroscience
Subjects
Details
- ISSN :
- 15537358
- Volume :
- 10
- Database :
- OpenAIRE
- Journal :
- PLoS Computational Biology
- Accession number :
- edsair.doi.dedup.....ce31fef3d28d6644ac22b9972939d3b8