An algorithmic information theory of consciousness

et al. 2017

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Objectives: Idiopathic REM sleep behavior disorder (RBD) is a serious risk factor for neurodegenerative processes such as Parkinson's disease (PD). We investigate the use of EEG algorithmic complexity derived metrics for its prognosis. Methods:We analyzed resting state EEG data collected from 114 idiopathic RBD patients and 83 healthy controls in a longitudinal study forming a cohort in which several RBD patients developed PD or dementia with Lewy bodies.Multichannel data from ∼5 minute recordings was converted to spectrograms and their algorithmic complexity estimated using Lempel-Ziv-Welch compression (LZW).Results: Complexity measures and entropy rate displayed statistically significant differences between groups. Results are compared to those using the ratio of slow to fast frequency power, which they are seen to complement by displaying increased sensitivity even when using a few EEG channels.Conclusions: Poor prognosis in RBD appears to be associated with decreased * Corresponding author, giulio.ruffini@neuroelectrics.com, +1 617-899 6911 Preprint submitted to Clinical NeurophysiologyDecember 10, 2017. CC-BY-ND 4.0 International license peer-reviewed) is the author/funder. It is made available under a The copyright holder for this preprint (which was not . http://dx.doi.org/10.1101/200543 doi: bioRxiv preprint first posted online Oct. 9, 2017; complexity of EEG spectrograms stemming in part from frequency power imbalances and cross-frequency amplitude coupling.Significance: Algorithmic complexity metrics provide a robust, powerful and complementary way to quantify the dynamics of EEG signals in RBD with links to emerging theories of brain function stemming from algorithmic information theory.

Section: Discussionsupporting

confidence: 87%

“…where K(x, y) denotes the complexity of the concatenated strings, and where we again approximate Kolmogorov complexity by LZW description length (see [11], annotated version). We now define the mutual algorithmic information coefficient between to strings to be µ 0 (x, y) = I K (x : y)…”

Section: F Mutual Informationmentioning

confidence: 99%

Algorithmic complexity of EEG for prognosis of neurodegeneration in idiopathic rapid eye movement behavior disorder (RBD)

Ruffini

Ibañez

et al. 2017

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“…This is translated into physiological signals with long-range correlations across various spatio-temporal scalesa behavior that is named selforganizationthat indicate the presence of self-invariant and self-similar structures (Pritchard and Duke, 1995). The self-organizational properties of a complex system can be quantified by estimating its dimension (Theiler, 1990), or its ability to compress information (Cover and Thomas, 2012;Ruffini, 2017a).…”

Section: Introductionmentioning

confidence: 99%

“…Different entropy measures as well as the measure of compressibility can be employed for this. Ruffini (2017a) recently proposed a theory of consciousness that considers the brain an engine that strives to model the world with simplicity, while learning it is a result of exchanging information with it. According to this theory, the ability of the brain to compress information is an indicator of consciousness.…”

Section: Introductionmentioning

confidence: 99%

Evaluating Complexity of Fetal MEG Signals: A Comparison of Different Metrics and Their Applicability

Moser

Bensaid

et al. 2019

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In this work, we aim to investigate whether information based metrics of neural activity are a useful tool for the search for consciousness before and shortly after birth. Neural activity is measured using fetal magnetoencephalography (fMEG) in human fetuses and neonates. Based on recent theories on consciousness, information-based metrics are established to measure brain complexity and to assess different levels of consciousness. Different metrics (measures of entropy, compressibility and fractality) are, thus, explored in a reference population and their usability is evaluated. For comparative analysis, two fMEG channels were selected: one where brain activity was previously detected and one at least 15cm away, that represented a control channel. The usability of each metric was evaluated and results from the brain and control channel were compared. Concerning the ease of use with fMEG data, Lempel-Ziv-Welch (LZW) compression was evaluated as best, as it is unequivocal and needs low computational effort. The fractality measures have a high parameter space and therefore forfeit comparability, while entropy measures require a higher computational effort and more parameters to adjust compared to LZW. Comparison of a channel with brain activity and a control channel in neonatal recordings showed significant differences in most complexity metrics. This clear difference can be seen as proof of concept for the usability of complexity metrics in fMEG. For fetal data, this comparison produced less clear results which can be related to leftover maternal signals included in the control channel. Further work is necessary to conclusively interpret results from the analysis of fetal recordings. Yet this study shows that complexity metrics can be used for fMEG data on early consciousness and the evaluation gives a guidance for future work. The inconsistency of results from different metrics highlights the challenges of working with complexity metrics as neural correlates of consciousness, as well as the caution one should apply to interpret them.

“…A wide range of cognitive functions are mediated by the dynamic modulation of oscillatory activity within and between different brain regions. The alpha rhythm (8)(9)(10)(11)(12)(13) has been associated to top-down processing [5,6], mediating attentional processes [7] and linked to functions such as working memory or visual perception. High frequency gamma rhythms Hz) have been associated with feature binding [8], learning or attention [3].…”

Section: Introductionmentioning

confidence: 99%

Occipital tACS bursts during a visual task impact ongoing neural oscillation power, coherence and LZW complexity

Castellano

Ibanez-Soria

et al. 2017

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Additional Title Page Footnotes:• We introduce a bursting tACS protocol to study semi-concurrent tACS effects in the visual system and their impact on behavior as measured by reaction time.• Burst 10 Hz tACS (tACS 10 ) applied to the visual cortex entrained γ-oscillations and increased RTs in a change-ofspeed detection visual task more than 70 Hz tACS (tACS 70 ) or Control conditions. • Burst tACS 10 also decreased amplitude of the P300 peak, while increasing α-power and γ-LZW complexity.• Physiological and behavioral impact of occipital tACS 10 and tACS 70 was frequency-specific. tACS 70 reduced γ-oscillations after 20min of tACS stimulation.• Cognitive task may determine cortical excitation levels as measured by complexity metrics, as lower γ-LZW complexity correlates to faster reaction times. SUMMARY:Little is known about the precise neural mechanisms by which tACS affects the human cortex. Current hypothesis suggest that transcranial current stimulation (tCS) can directly enhance ongoing brain oscillations and induce long-lasting effects through the activation of synaptic plasticity mechanisms [1]. Entrainment has been demonstrated in in-vitro studies, but its presence in non-invasive human studies is still under debate [2,3]. Here, we aim to investigate the immediate and shortterm effects of tACS bursts on the occipital cortex of participants engaged in a change-of-speed detection task, a task that has previously reported to have a clear physiology-behavior relationship, where trials with faster responses also have increased power in γ-oscillations (50-80 Hz) [4]. The dominant brain oscillations related to the visual task are modulated using multichannel tACS at 10 and 70 Hz within occipital cortex. We found that tACS stimulation at 10 Hz (tACS 10 ) enhanced both α (8-13 Hz) and γ oscillations, in hand with an increase in reaction time (RT) in the change-of-speed detection visual task. On the other hand, tACS at 70Hz desynchronized visual cortices, impairing both phase-locked and endogenous γ-power while increasing RT. While both tACS protocols seem to revert the relationship reported in [4], we argue that tACS produces a shift in attentional resources within visual cortex while leaving unaltered the resources required to conduct the task. This theory is supported by the fact that the correlation between fast RT and high γ-power trials is maintained for tACS sessions too. Finally, we measured cortical excitability by analyzing Event-Related-Potentials (ERP) Lempel-Ziv-Welch Complexity (LZW). In control sessions we observe that lower γ-LZW complexity correlates to faster reaction times. Both metrics are altered by tACS stimulation, as tACS 10 decreased amplitude of the P300 peak, while increasing γ-LZW complexity. To this end, our study highlights the nonlinear cross-frequency interaction between exogenous stimulation and endogenous brain dynamics, and proposes the use of complexity metrics, as LZW, to characterize excitability patterns of cortical areas in a behaviorally relevant timescale. These insights w...