Neuronal Avalanches in the Resting MEG of the Human Brain

Data acquisition and preprocessing.

Spontaneous brain activity was recorded from healthy human subjects in the MEG core facility at the National Institutes of Health (NIH)–National Institute of Mental Health in the United States and the Medical Research Council Cognition and Brain Sciences Unit in Cambridge, United Kingdom(Shriki et al., 2011; an earlier version of this study). The NIH facility recorded activity from 104 subjects (38 males and 66 females; age, 31.8 ± 11.8 y) for 4 min at rest with eyes closed. The data were recorded using a CTF MEG system (CTF Systems). They were sampled at 600 Hz and band-pass filtered (1–80 Hz). The sensor array consisted of 275 axial first-order gradiometers. Two dysfunctional sensors were removed, leaving 273 sensors in the analysis. Analysis was performed directly on the axial gradiometer waveforms and on data transformed to planar gradiometers using the FieldTrip toolbox in MATLAB (MathWorks).

The Cambridge facility used an Elekta Neuromag MEG system to record activity from 20 participants (15 males and 5 females; age, 28.8 ± 7.2 y) for 3.5 min at rest with eyes closed. Maxfilter (Elekta Neuromag) was used to remove external noise with signal space separation (Taulu et al., 2004) and to correct for head movements (Taulu and Simola, 2006). Independent component analysis was used to remove independent components associated with eye movements (unless otherwise specified). The data were sampled at 1 kHz, down-sampled to 250 Hz, and band-pass filtered (1–80 Hz). The sensor array consisted of 102 pairs of planar gradiometers. Fifteen sensors were found to be associated with artifacts in many subjects and were removed, leaving 87 sensor pairs in the analysis.

Notch frequencies associated with alternating current of the electricity network were removed (60 Hz for the NIH data, 50 Hz for the Cambridge data). Power spectrum density functions were calculated for each sensor, averaged for each subject, and the exponent β was fit for 10–50 Hz.

Independent components associated with the magnetocardiogram (MCG) were removed. Independent component analysis was performed using the FieldTrip MATLAB toolbox. MCG components have a highly characteristic waveform with sharp deflections at regular intervals corresponding to the heartbeat. We therefore identified MCG components based on their temporal regularity. For analysis, we used the 25 independent components that had the highest variance for each subject. Using a threshold (±3 SD; see also Signal Discretization below), discrete suprathreshold events were identified in the waveform associated with each component. We then examined the statistics of the inter-event intervals by calculating the coefficient of variation (CV). In expectation with the regularity of heartbeat artifacts, the CV distribution was bimodal; a significant number of components had very low CVs that were typically between 0 and 0.7 (0.20 ± 0.18 mean ± SD; n = 104). In contrast, most other components centered at 1 with some components reaching up to 6. The width of the central peak was relatively narrow toward smaller values, resulting in a clear separation of the cluster of CV values below 0.7 (the SD of a Gaussian fit to the left side of the central peak was 0.06). Visual inspection of the actual waveforms revealed regular spikes at heartbeat frequency, confirming our identification of MCG components based on low CV values. In most NIH subjects, we found between one and three relevant components and a few subjects did not have any MCG-associated component. For most Cambridge subjects, there was no MCG-associated component and a few had a single relevant component. Sensor waveforms were then reconstructed without MCG components using the FieldTrip MATLAB toolbox.

Signal discretization.

For each sensor, positive and negative excursions beyond a threshold were identified. A single event was identified per excursion at the most extreme value (maximum for positive excursions and minimum for negative excursions; Fig. 1A). Comparison of the signal distribution to the best fit Gaussian (Fig. 1B) indicates that the two distributions start to deviate from one another at ∼±2.7 SD. Therefore, thresholds smaller than ±2.7 SD will lead to the detection of many events related to noise in addition to real events, whereas much larger thresholds will miss many of the real events. To strike a compromise, the thresholds chosen were ±3 SD, which amounts to a false positive probability of ∼0.1%. As will be shown further below (Fig. 5), similar results were found with thresholds in the range of ±2.7 to ±4.2 SD (Fig. 5E), as well as when using a peak detection method that considers all local extremum points beyond threshold as events (Fig. 5F).

All planar gradiometers are in orthogonal pairs tangential to the skull. This refers to both the virtual planar gradiometers in the NIH data and the original planar gradiometers in the Cambridge data. Event rasters of the gradiometer pairs were combined into a single channel, or sensor, using an OR operation. That is, events observed at the same time in a pair of gradiometers were counted as one event.

Effect of signal discretization on pairwise correlations.

For each sensor, we calculated two event-triggered averages (ETAs), one for positive and one for negative events (±350 ms relative to the event; Fig. 1C). To reconstruct the continuous sensor signal, we convolved the positive ETA with the train of positive events, convolved the negative ETA with the train of negative events, and summed the two. For each pair of sensors, we calculated the corresponding cross-correlation based on the original signals and on the reconstructed signals. Scatter plots of the pairwise correlations for the original and reconstructed signals are shown in Fig. 1D. To evaluate the effect of signal discretization on the correlations, we calculated the correlation coefficient for these values for each subject.

Cascade-size distributions and power law statistics.

The time series of events obtained from each sensor was individually discretized with time bins of duration Δt. The timescale of the analysis, Δt, was explored systematically in multiples of Δt_min, which was the inverse of the data acquisition sampling rate for each system. A cascade was defined as a continuous sequence of time bins in which there was an event on any sensor, ending with a time bin with no events on any sensor. The number of events on all sensors in a cascade was defined as the cascade size.

We analyzed the avalanche size distribution's fit to a power law using methods described previously (Clauset et al., 2007; Klaus et al., 2011). The candidate distributions were the power law and exponential distributions, each limited to the range between a minimum and a maximum size. This focus on power laws stems from the theory of critical branching processes, which predicts power law behavior (Harris, 1989). We note that alternative heavy-tail distributions such as the gamma and log-normal distributions are characterized by two parameters and can give better fits than power laws or single exponentials simply due to the additional degree of freedom.

Power laws were modeled as follows: Exponential functions were modeled as follows: where C_{α and} C_λ are normalization factors. The parameter x_min was set to 1, the minimal avalanche size, and x_max was set to 1.5 times the total number of sensors included in the analysis, which included virtually all observed avalanches.

Assuming independence of avalanche sizes and a sample of n avalanches, the likelihood of each model, given a parameter α or λ, is as follows: For ease of computation, the logarithms of the likelihoods can be calculated instead, producing the log-likelihood as follows: The best fit parameters for both distributions (α̂ and λ̂) can then be calculated by maximizing this log-likelihood as a function of the parameter. To determine whether the power law or exponential distribution was a better fit to the data, the log of the likelihood-ratio (LLR) was taken with the best fit parameters as follows: If the LLR is positive, the power law model is more likely, and if it is negative, the exponential model is more likely. If the LLR is zero, neither distribution is more likely. To determine whether the LLR was significantly different from zero, the p-value of the LLR was calculated as follows: where: with ℓ̅_α = ℓ(α | x⁽ⁿ⁾)/n and ℓ̅_λ = ℓ(λ | x⁽ⁿ⁾)/n.

For further control, surrogate data were generated for each subject by shuffling the component frequencies of each individual sensor, which maintains the power spectrum but destroys phase relationships across frequencies and sensors.

Finite-size scaling and coarse-graining of sensor arrays.

To study the effect of sensor array size on the cascade size distributions, cascades were identified using data from contiguous subsections of the array with N sensors. The distributions were calculated for cascade size, S, and normalized cascade size, Z = S/N. The power law cutoff was identified as the right-most point in the distribution before the tail of the distribution consistently remained below the fitted power law. Finite size scaling was quantified by correlating the size of the cutoff with the size of the sensor array used for avalanche analysis. Coarse graining of the sensor array was performed by grouping clusters of neighboring sensors and combining their event rasters with a logical OR operation. Therefore, multiple events observed during the same time bin for any sensor group were counted as one event.

Estimation of the branching parameter.

The branching parameter σ was estimated by calculating the ratio of the number of events in the second time bin of a cascade to that in the first time bin. This ratio was averaged over all cascades for each subject with no exclusion criteria (Beggs and Plenz, 2003) as follows: where N_av is the total number of avalanches in the dataset and n_events represents the number of events in a particular bin. Note that for single bin cascades, the second bin is an empty bin and therefore the corresponding ratio is 0.

Phase synchronization analysis.

Kitzbichler et al. (Kitzbichler et al., 2009) suggested probing for critical dynamics using phase synchronization, which we both replicated and simplified here. The metric involves measuring the durations of phase synchrony between pairs of sensors and then examining the distribution of such phase synchrony durations across all channel pairs.

The data in each pair of channels were first transformed into a complex representation of instantaneous amplitude and phase as follows: The method for this transformation used in Kitzbichler et al. (2009), along with an additional, simplified method, are described below. Once an amplitude and phase representation is obtained, the instantaneous phase difference between two channels can be computed as follows: Due to rapid noise fluctuations, a more reliable measure is obtained by smoothing as follows: where 〈 … 〉 denotes a running average with a time window of Δt.

Between two channels, a period of phase synchrony is identified when both the phase difference is below a threshold and the amplitudes of the channels are above a threshold, as follows: The durations of all such periods are recorded for all channel pairs. In Kitzbichler et al., (2009), it was found that the probability distribution of these phase locking intervals (PLIs) follows a power law in the Ising and Kuramoto models when at criticality, as well as in human resting state fMRI and MEG signals.

To characterize phase synchronization among channels, the raw time series data were transformed into a complex representation of instantaneous amplitude and phase. In Kitzbichler et al. (2009), this was done by filtering with Hilbert wavelet pairs, as described previously (Selesnick, 2001; Whitcher et al., 2005). Results for this method are shown in Figure 9A, B. In addition, a simplified method was used in which the signal was first band-pass filtered, and then the Hilbert transform was applied to produce the instantaneous amplitude and phase. Specifically, the signals in each channel, x(t), were first filtered in the band of interest using a 25-pole finite impulse response filter. The filter was applied first forward and then backward in time to eliminate phase distortions. The complex analytic representation of the filtered signal, y(t), was calculated as follows: where y_H(t) is the Hilbert transform, defined as follows: The Hilbert transform represents the convolution of the signal with the function 1πt, but because the integral does not converge, the Cauchy principal value of the integral (denoted as p.v.) is calculated. Results for this method are depicted in Figure 9C–H.

Model for testing the effect of linear mixing among sensors.

The analyses we performed were based on sensor data. Each MEG sensor linearly sums contributions from many sources and some overlap in the sensitivity of nearby sensors exists. Therefore, the transformation from sources to sensors involves a certain degree of linear mixing of the underlying sources. To evaluate the effect of linear mixing on the results, we ran simulations of a simple neural network with a two-dimensional layout and added a layer of simulated sensors, which linearly mix the activations in the underlying network.

The model was based on one described previously (Shew et al., 2009) and consisted of N = 2025 binary neurons arranged in a 45 × 45 grid. The synaptic coupling strengths are denoted by p_ij and represent the probability that neuron i will spike at time t + 1 if neuron j was the only one that spiked at time t. In general, if a set of neurons J(t) spikes at time t, the neurons obey the following dynamics: where Θ[x] is the unit step function, p_iJ(t)=1−∏j∈J(t)(1−pij), and ζ(t) is a random number from a uniform distribution in [0,1]. The coupling strengths, p_ij, are random and fall with the distance between neurons. Specifically, we used a Gaussian envelope with a SD of four times the distance between neighboring neurons. The branching parameter of the network is defined by σ ≡ N⁻¹ ∑i,jpij and reflects the mean strength of the outgoing connections from each neuron. When the branching parameter is 1, the system is critical and each neuron will activate on average one neuron in the next time step. A cascade was started by setting a single (randomly chosen) neuron to 1 and ended when there was no activity on the array.

The sensor layer consisted of M = 64 sensors arranged in an 8 × 8 grid. To avoid boundary effects, the sensor array was located within the neuron grid with wide margins on each side. Specifically, we first created a 12 × 12 sensor grid covering the total area of the neuron grid and then considered only the 8 × 8 central sensors. Therefore, the distance between neighboring sensors, denoted by d, was exactly four times the distance between neighboring neurons and the margins on each side corresponded to two times the distance between neighboring sensors, or equivalently, to eight times the distance between neighboring neurons. Each sensor summed the activity of the underlying neurons with a Gaussian weighting function centered around its location on the grid. The sum of the weights was normalized to 1. The SD of this Gaussian was varied from 0.5 d (small overlap) to 1.5 d (large overlap). A threshold function was then applied to the summed activation, with the threshold proportional to the peak value of the Gaussian. The proportion factor was chosen to be 0.35. High threshold values result in misdetection of events on the grid and thus in underestimation of the branching parameter. Similarly, low threshold values tend to result in multiple events on the sensor array in response to a single event on the neuron grid, which may lead to underestimation of size 1 cascades. Our choice reflected a tradeoff between these two effects, but the results were robust for a wide range of values. After the thresholding operation, in each time step, there was an N-by-1 binary vector representing the network state and an M-by-1 binary vector representing the corresponding state of the sensor array. The simulation was run for 60,000 cascades. The power low exponent and the branching parameter of the sensor array were estimated in the same way as in the MEG data. In particular, the branching parameter was estimated using the ratio of events in the first two time steps of each cascade.

We also simulated independent Poisson processes on the neuron grid and recorded the corresponding activity on the sensor array. In each time step of a cascade, neuronal activations were chosen from the Poisson process and the cascade terminated when no neuron was active. The mean rate of the Poisson process was set to match the mean activation probability of neurons in the critical network simulation.