The Spectral Diversity of Resting-State Fluctuations in the Human Brain

Kalcher, Klaudius; Boubela, Roland N.; Huf, Wolfgang; Bartova, Lucie; Kronnerwetter, Claudia; Derntl, Birgit; Pezawas, Lukas; Filzmoser, Peter; Našel, Christian; Moser, Ewald

doi:10.1371/journal.pone.0093375

Cited by 67 publications

(66 citation statements)

References 25 publications

(29 reference statements)

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“…The reduction of slow-5 fALFF was likely not due to changes at the higher frequencies (0.073-0.192 Hz), as power in those frequencies is minimal. This was demonstrated in this study as well as in prior studies (Calhoun Zuo et al, 2010), Furthermore, low-TR fMRI (Kalcher et al, 2014) and MR-Encephalography (Lee et al, 2013) studies, techniques offering much improved temporal resolution, also confirmed the small contributions of high oscillations during the resting state.…”

Section: Discussionsupporting

confidence: 89%

Implication of the Slow-5 Oscillations in the Disruption of the Default-Mode Network in Healthy Aging and Stroke

Nair

Mossahebi

et al. 2016

Brain Connectivity

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The processes of normal aging and aging-related pathologies subject the brain to an active re-organization of its brain networks. Among these, the default-mode network (DMN) is consistently implicated with a demonstrated reduction in functional connectivity within the network. However, no clear stipulation on the underlying mechanisms of the de-synchronization has yet been provided. In this study, we examined the spectral distribution of the intrinsic low-frequency oscillations (LFOs) of the DMN sub-networks in populations of young normals, older subjects, and acute and subacute ischemic stroke patients. The DMN sub-networks were derived using a midorder group independent component analysis with 117 eyes-closed resting-state functional magnetic resonance imaging (rs-fMRI) sessions from volunteers in those population groups, isolating three robust components of the DMN among other resting-state networks. The posterior component of the DMN presented noticeable differences. Measures of amplitude of low-frequency fluctuation (ALFF) and fractional ALFF (fALFF) of the network component demonstrated a decrease in resting-state cortical oscillation power in the elderly (normal and patient), specifically in the slow-5 (0.01-0.027 Hz) range of oscillations. Furthermore, the contribution of the slow-5 oscillations during the resting state was diminished for a greater influence of the slow-4 (0.027-0.073 Hz) oscillations in the subacute stroke group, not only suggesting a vulnerability of the slow-5 oscillations to disruption but also indicating a change in the distribution of the oscillations within the resting-state frequencies. The reduction of network slow-5 fALFF in the posterior DMN component was found to present a potential association with behavioral measures, suggesting a brain-behavior relationship to those oscillations, with this change in behavior potentially resulting from an altered network integrity induced by a weakening of the slow-5 oscillations during the resting state. The repeated identification of those frequencies in the disruption of DMN stresses a critical role of the slow-5 oscillations in network disruption, and it accentuates the importance of managing those oscillations in the health of the DMN.

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Section: Discussionsupporting

confidence: 89%

Implication of the Slow-5 Oscillations in the Disruption of the Default-Mode Network in Healthy Aging and Stroke

Nair

Mossahebi

et al. 2016

Brain Connectivity

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“…Thus, in this work, we simply establish the feasibility of multiband imaging as a viable method to investigate rs-fMRI physiology. While slice-accelerated imaging offers alluring potential and its reliability in multiple applications has been tested (Kalcher et al, 2014;Xu et al, 2013) it will need to undergo further tests of time. Fig.…”

Section: Potential Caveatsmentioning

confidence: 99%

Mapping the end-tidal CO2 response function in the resting-state BOLD fMRI signal: Spatial specificity, test–retest reliability and effect of fMRI sampling rate

et al. 2015

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“…The observed distributions of node degree and relative Fourier amplitude of low-frequency activity are in close agreement with existing reports considering the two parameters separately and are unlikely to be driven primarily by noise. [13][14][15][16]18,28,29,37,61 This spectral heterogeneity points to different dynamics of underlying neural activity. Even though BOLD signals are not well-suited for non-linear dynamical analysis due to short time-series length, undersampling, physiological noise, and confounds from neurovascular coupling, we attempted Figure 4(a) for network diagram).…”

Section: Discussionmentioning

confidence: 99%

“…[25][26][27] Recent increases in the sampling rate of functional MRI have made it possible to study inter-regional spectral differences, often represented with power-law frequency scaling coefficients or relative Fourier amplitudes of low frequencies (typically <0.1 Hz). 19,28,29 At the same time, the fact that realistic RSNs emerge even in highly simplified simulation scenarios, for example, from networked phase (Kuramoto) oscillators or discrete excitable units, raises the intriguing possibility of recapitulating some dynamical phenomena underlying brain function in other physical systems, where direct manipulation of connectivity is possible and causal relationships between connectivity and non-linear dynamics can be explored experimentally. [8][9][10]30 In particular, it has recently been shown that singletransistor oscillators can exhibit strikingly complex activity depending on an easily tunable control parameter (DC voltage source series resistance), oscillating periodically, chaotically, or close to criticality.…”

Section: Introductionmentioning

confidence: 99%

Synchronization, non-linear dynamics and low-frequency fluctuations: Analogy between spontaneous brain activity and networked single-transistor chaotic oscillators

Minati¹,

Chiesa²,

Tabarelli³

et al. 2015

Chaos: An Interdisciplinary Journal of Nonlinear Science

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In this paper, the topographical relationship between functional connectivity (intended as inter-regional synchronization), spectral and non-linear dynamical properties across cortical areas of the healthy human brain is considered. Based upon functional MRI acquisitions of spontaneous activity during wakeful idleness, node degree maps are determined by thresholding the temporal correlation coefficient among all voxel pairs. In addition, for individual voxel time-series, the relative amplitude of low-frequency fluctuations and the correlation dimension (D2), determined with respect to Fourier amplitude and value distribution matched surrogate data, are measured. Across cortical areas, high node degree is associated with a shift towards lower frequency activity and, compared to surrogate data, clearer saturation to a lower correlation dimension, suggesting presence of non-linear structure. An attempt to recapitulate this relationship in a network of single-transistor oscillators is made, based on a diffusive ring (n = 90) with added long-distance links defining four extended hub regions. Similarly to the brain data, it is found that oscillators in the hub regions generate signals with larger low-frequency cycle amplitude fluctuations and clearer saturation to a lower correlation dimension compared to surrogates. The effect emerges more markedly close to criticality. The homology observed between the two systems despite profound differences in scale, coupling mechanism and dynamics appears noteworthy. These experimental results motivate further investigation into the heterogeneity of cortical non-linear dynamics in relation to connectivity and underline the ability for small networks of single-transistor oscillators to recreate collective phenomena arising in much more complex biological systems, potentially representing a future platform for modelling disease-related changes.

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The Spectral Diversity of Resting-State Fluctuations in the Human Brain

Cited by 67 publications

References 25 publications

Implication of the Slow-5 Oscillations in the Disruption of the Default-Mode Network in Healthy Aging and Stroke

Implication of the Slow-5 Oscillations in the Disruption of the Default-Mode Network in Healthy Aging and Stroke

Mapping the end-tidal CO2 response function in the resting-state BOLD fMRI signal: Spatial specificity, test–retest reliability and effect of fMRI sampling rate

Synchronization, non-linear dynamics and low-frequency fluctuations: Analogy between spontaneous brain activity and networked single-transistor chaotic oscillators

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