Neuronal Oscillations with Non-sinusoidal Morphology Produce Spurious Phase-to-Amplitude Coupling and Directionality
Publication year
2016Number of pages
17 p.
Source
Frontiers in Computational Neuroscience, 10, (2016), pp. 1-17, article 87ISSN
Publication type
Article / Letter to editor
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Organization
PI Group Neuronal Oscillations
Psychiatry
PI Group MR Techniques in Brain Function
Journal title
Frontiers in Computational Neuroscience
Volume
vol. 10
Languages used
English (eng)
Page start
p. 1
Page end
p. 17
Subject
150 000 MR Techniques in Brain Function; 160 000 Neuronal Oscillations; 160 028 Pharmacological modulation of alpha and gamma oscillationsAbstract
Neuronal oscillations support cognitive processing. Modern views suggest that neuronal oscillations do not only reflect coordinated activity in spatially distributed networks, but also that there is interaction between the oscillations at different frequencies. For example, invasive recordings in animals and humans have found that the amplitude of fast oscillations (> 40 Hz) occur non-uniformly within the phase of slower oscillations, forming the so-called cross-frequency coupling (CFC). However, the CFC patterns be influenced by features in the signal that do not relate to underlying physiological interactions. For example, CFC estimates may be sensitive to spectral correlations due to non-sinusoidal properties of the alpha band wave morphology. To investigate this issue, we performed CFC analysis using experimental and synthetic data. The former consisted in a double-blind magnetoencephalography pharmacological study in which participants received either placebo, 0.5 mg or 1.5 mg of lorazepam (LZP; GABAergic enhancer) in different experimental sessions. By recording oscillatory brain activity with during rest and working memory (WM), we were able to demonstrate that posterior alpha (8 – 12 Hz) phase was coupled to beta-low gamma band (20 – 45 Hz) amplitude envelope during all sessions. Importantly, bicoherence values around the harmonics of the alpha frequency were similar both in magnitude and topographic distribution to the cross-frequency coherence (CFCoh) values observed in the alpha-phase to beta-low gamma coupling. In addition, despite the large CFCoh we found no significant cross-frequency directionality (CFD). Critically, simulations demonstrated that a sizable part of our empirical CFCoh between alpha and beta-low gamma coupling and the lack of CFD could be explained by two-three harmonics aligned in zero phase-lag produced by the physiologically characteristic alpha asymmetry in the amplitude of the peaks relative to the troughs. Furthermore, we showed that periodic signals whose waveform deviate from pure sine waves produce non-zero CFCoh with predictable CFD. Our results reveal the important role of the non-sinusoidal wave morphology on state of the art CFC metrics and we recommend caution with strong physiological interpretations of CFC and suggest basic data quality checks to enhance the mechanistic understanding of CFC.
This item appears in the following Collection(s)
- Academic publications [246515]
- Donders Centre for Cognitive Neuroimaging [4040]
- Electronic publications [134102]
- Faculty of Medical Sciences [93308]
- Open Access publications [107633]
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