Abstract
Brain synchronizations are orchestrated from neuronal oscillations through frequency interactions, such as the alpha rhythm during relaxation. Nevertheless, how the intrinsic interaction forges functional integrity across brain segregations remains elusive, thereby motivating recent studies to localize frequency interactions of resting-state fMRI (rs-fMRI). To this point, we aim to unveil the fMRI-based spectral interactions using the time-frequency (TF) analysis; however, Fourier-based TF analyses impose restrictions on revealing frequency interactions given the limited time points in fMRI signals. Instead of using the Fourier-based wavelet analysis to identify the fMRI frequency of interests, we employed the Hilbert–Huang transform (HHT) for probing the specific frequency contribution to the functional integration, called ensemble spectral interaction (ESI). By simulating data with time-variant frequency changes, we demonstrated the Hilbert TF maps with high spectro-temporal resolution and full accessibility in comparison with the wavelet TF maps. By detecting amplitude-to-amplitude frequency couplings (AAC) across brain regions, we elucidated the ESI disparity between the eye-closed (EC) and eye-open (EO) conditions in rs-fMRI. In the visual network, the strength of the spectral interaction within 0.03–0.04 Hz was amplified in EC compared with that in EO condition, whereas a canonical connectivity analysis did not present differences between conditions. Collectively, leveraging from the instantaneous frequency of HHT, we firstly addressed the ESI technique to map the fMRI-based functional connectivity in a brand-new AAC perspective. The ESI possesses potential in elucidating the functional connectivity at specific frequency bins, thereby providing additional diagnostic merits for future clinical neuroscience.
Highlights
IntroductionThe importance of brain science lies in the time-variant synchronization and desynchronization of neuron assemblies across space, forming dynamic regional oscillations over a wide range of frequency complexes
The scanning order of the EC/EO conditions was counterbalanced to reduce the systematic bias in resting-state functional magnetic resonance imaging (fMRI) (rs-fMRI) sessions
Because the simulated signals depicted the relationship between frequency modulations, the amplitude-to-amplitude frequency couplings (AAC) map was expected to identify spectral interactions between the two Hilbert TF maps
Summary
The importance of brain science lies in the time-variant synchronization and desynchronization of neuron assemblies across space, forming dynamic regional oscillations over a wide range of frequency complexes. Several academic studies have discovered the importance of neural oscillations in daily life by demonstrating associations between electrophysiological components (e.g., local field potential, LFP) on the basis of multi-type physiological states or cognitive processes. The majority of research articles on electrophysiological signals have focused on the correspondence between the power of high-frequency oscillations and the performances of task engagements. A recent perspective has attracted public attention to endogenous long-range synchronizations in neural systems, in low-frequency oscillations. Studies have indicated that infra-slow (0.01–0.10 Hz) electrophysiological fluctuations reflect the integrations within concurrently active neuronal communities [3], plausibly associating with the neuroplasticity processes such as memory consolidation [4]. By combining the electrophysiological measure and functional magnetic resonance imaging (fMRI) signal in the resting state [5], Wilson et al
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