Differentiating resting brain states using ordinal symbolic analysis

Quintero-Quiroz, C.; Montesano, Luis; Pons, Antonio J.; Torrent, M. C.; García‐Ojalvo, Jordi; Masoller, Cristina

doi:10.1063/1.5036959

Cited by 26 publications

(20 citation statements)

References 28 publications

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“…Our study indicates that the only information quantifier that allows distinguishing between eyes opened or closed in awake states is permutation entropy. This is in agreement with recent work [55], in which it was possible to detect changes of states between eyes open and eyes closed in human scalp electroencephalography using permutation entropy.…”

Section: Discussionsupporting

confidence: 93%

Complexity of brain dynamics as a correlate of consciousness in anaesthetized monkeys

Fuente

Garcia

Guevara

et al. 2021

Preprint

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The use of anaesthesia is a fundamental tool in the investigation of consciousness. Anesthesia procedures allow to investigate different states of consciousness from sedation to deep anesthesia within controlled scenarios. In this study we use information quantifiers to measure the complexity of electrocorticogram recordings in monkeys. We apply these metrics to compare different stages of general anesthesia for evaluating consciousness in several anesthesia protocols. We find that the complexity of brain activity can be used as a correlate of consciousness. For two of the anaesthetics used, propofol and medetomidine, we find that the anaesthetised state is accompanied by a reduction in the complexity of brain activity. On the other hand we observe that use of ketamine produces an increase in complexity measurements. We relate this observation with increase activity within certain brain regions associated with the ketamine used doses. Our measurements indicate that complexity of brain activity is a good indicator for a general evaluation of different levels of consciousness awareness, both in anesthetized and non anesthetizes states.

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Section: Discussionsupporting

confidence: 93%

Complexity of brain dynamics as a correlate of consciousness in anaesthetized monkeys

Fuente

Garcia

Guevara

et al. 2021

Preprint

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“…In contrast to other methods, PeEn is a time-series complexity measure that is simple to implement, is robust to noise and short time-series, and works for arbitrary data sets. 13,16,17,[20][21][22][23][24][25][26] In particular, it has been shown that PeEn applied to EEG signals captures different states associated with the level of consciousness, both during anesthesia [26][27][28][29] and sleep. 30,31 Hence, in order to study the thalamo-cortical function during W and sleep, PeEn is a practical and reliable method, where results can be understood from primary principles, and can be related to the signal characteristics.…”

Section: Introductionmentioning

confidence: 99%

Decreased electrocortical temporal complexity distinguishes sleep from wakefulness

González

Cavelli

Mondino

et al. 2019

Preprint

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In most mammals, the sleep-wake cycle is constituted by three behavioral states: wakefulness (W), non-NREM (NREM) sleep, and REM sleep. These states are associated with drastic changes in cognitive capacities, mostly determined by the function of the thalamo-cortical system. The intra-cranial electroencephalogram or electocorticogram (ECoG), is an important tool for measuring the changes in the thalamo-cortical activity during W and sleep. In the present study we analyzed broad-band ECoG recordings of the rat by means of a time-series complexity measure that is easy to implement and robust to noise: the Permutation Entropy (PeEn). We found that PeEn is maximal during W and decreases during sleep. These results bring to light the different thalamo-cortical dynamics emerging during sleep-wake states, which are associated with the well-known spectral changes that occur when passing from W to sleep. Moreover, the PeEn analysis allows to determine behavioral states independently of the electrodes' cortical location, which points to an underlying global pattern in the signal that differs among the cycle states that is missed by classical methods. Consequently, our data suggest that PeEn analysis of a single EEG channel could allow for cheap, easy, and efficient sleep monitoring. 10/11

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“…Ordinal patterns (OPs) are a symbolic approach to time series analysis that was originally introduced by Bandt and Pompe (2002). Since then, OP based methods have successfully been used in the analyses of biomedical data (Keller et al, 2007b;Amigó et al, 2010Amigó et al, , 2015Parlitz et al, 2012;Graff et al, 2013;Kulp et al, 2016;McCullough et al, 2017) and specifically EEG recordings (Keller et al, 2007a(Keller et al, , 2014Ouyang et al, 2010;Schinkel et al, 2012Schinkel et al, , 2017O'Hora et al, 2013;Rummel et al, 2013;Shalbaf et al, 2015;Unakafov, 2015;Cui et al, 2016;Quintero-Quiroz et al, 2018). Statistics based on ordinal pattern have been shown to be robust to noise (Parlitz et al, 2012;Quintero-Quiroz et al, 2015) and can be used to define advanced concepts for quantifying information flow (Staniek and Lehnertz, 2008;Amigó et al, 2016) or to derive transition networks in state space from observed time series (McCullough et al, 2015;Zhang et al, 2017).…”

Section: Ordinal Pattern Statistics and Mutual Informationmentioning

confidence: 99%

“…Therefore, we used ordinal pattern (OP) statistics (Bandt and Pompe, 2002) for characterizing our data which has been shown to be a robust method for analysing physiological time series (Keller et al, 2007a(Keller et al, , 2014Parlitz et al, 2012;Amigó et al, 2015;Unakafov, 2015). For example, OP analysis has been used to separate healthy subjects from patients suffering from congestive heart failure (Parlitz et al, 2012) or to differentiate between different experimental conditions in EEG recordings (Unakafov, 2015;Quintero-Quiroz et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Extracting Robust Biomarkers From Multichannel EEG Time Series Using Nonlinear Dimensionality Reduction Applied to Ordinal Pattern Statistics and Spectral Quantities

et al. 2021

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In this study, ordinal pattern analysis and classical frequency-based EEG analysis methods are used to differentiate between EEGs of different age groups as well as individuals. As characteristic features, functional connectivity as well as single-channel measures in both the time and frequency domain are considered. We compare the separation power of each feature set after nonlinear dimensionality reduction using t-distributed stochastic neighbor embedding and demonstrate that ordinal pattern-based measures yield results comparable to frequency-based measures applied to preprocessed data, and outperform them if applied to raw data. Our analysis yields no significant differences in performance between single-channel features and functional connectivity features regarding the question of age group separation.

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Differentiating resting brain states using ordinal symbolic analysis

Cited by 26 publications

References 28 publications

Complexity of brain dynamics as a correlate of consciousness in anaesthetized monkeys

Complexity of brain dynamics as a correlate of consciousness in anaesthetized monkeys

Decreased electrocortical temporal complexity distinguishes sleep from wakefulness

Extracting Robust Biomarkers From Multichannel EEG Time Series Using Nonlinear Dimensionality Reduction Applied to Ordinal Pattern Statistics and Spectral Quantities

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