Elsevier

Journal of Neuroscience Methods

Volume 243, 30 March 2015, Pages 94-102
Journal of Neuroscience Methods

Basic Neuroscience
Parametric estimation of cross-frequency coupling

https://doi.org/10.1016/j.jneumeth.2015.01.032Get rights and content
Under a Creative Commons license
open access

Highlights

  • We revisit the general linear model (GLM) approach to cross-frequency coupling.

  • Continuous time series were split into epochs for parametric statistical tests.

  • The GLM and permutation tests produced similar results in experimental data.

  • The GLM offers a good trade-off between computation time and statistical power.

  • Other predictors such as amplitude-amplitude coupling can be easily included.

Abstract

Background

Growing experimental evidence suggests an important role for cross-frequency coupling in neural processing, in particular for phase-amplitude coupling (PAC). Although the details of methods to detect PAC may vary, a common procedure to estimate the significance level is the comparison of observed values to those of at least 100 surrogate time series. When scanning large parts of the frequency spectrum and multiple recording sites, this could amount to very large computation times.

New method

We demonstrate that the general linear model (GLM) allows for a parametric estimation of significant PAC. Continuous recordings are split into epochs, of a few seconds duration, on which an F-test can be performed. We compared its performance against traditional non-parametric permutation tests in both simulated and experimental data.

Results

Our method was able to reproduce findings of phase-amplitude coupling in local field potential recordings obtained from the subthalamic nucleus in patients with Parkinson's disease. We also show that PAC may be detected between the subthalamic nucleus and cortical motor areas.

Comparison with existing method(s)

Although the GLM slightly underestimated significance compared to permutation tests in the simulations, for experimental data the two methods produced highly similar results. Computation times were drastically lower for the GLM. Furthermore, we demonstrate that the GLM can be easily extended by including additional predictors such as low-frequency amplitude to test for amplitude-amplitude coupling.

Conclusions

The GLM forms an adequate and computationally efficient approach for detecting cross-frequency coupling with the flexibility to add other explanatory variables of interest.

Keywords

Nested oscillations
Beta band
Deep brain stimulation (DBS)
Magnetoencephalography (MEG)
Power fluctuations
Connectivity

Cited by (0)