Reliability of Magnetoencephalography and High-Density Electroencephalography Resting-State Functional Connectivity Metrics

6533b851fe1ef96bd12a8d82

RESEARCH PRODUCT

Reliability of Magnetoencephalography and High-Density Electroencephalography Resting-State Functional Connectivity Metrics

Niels K. Focke Niels K. Focke Margherita Carboni Yiwen Li Hegner Christina Stier Christina Stier Silvia Vannoni Silvia Vannoni Justus Marquetand Christoph Braun

subject

Adult Male Computer science Rest High density Electroencephalography 050105 experimental psychology 03 medical and health sciences 0302 clinical medicine Neural Pathways Connectome medicine Humans 0501 psychology and cognitive sciences Resting state Reliability (statistics)Brain Mapping Connectivity MEG medicine.diagnostic_test Resting state fMRI business.industry General Neuroscience Functional connectivity 05 social sciences Brain Magnetoencephalography Reproducibility of Results Electroencephalography Pattern recognition Magnetoencephalography Reliability Magnetic Resonance Imaging Healthy Volunteers ddc:616.8 Benchmarking Female hd-EEG Artificial intelligence Nerve Net business Algorithms 030217 neurology & neurosurgery

description

Resting-state connectivity, for example, based on magnetoencephalography (MEG) or electroencephalography (EEG), is a widely used method for characterizing brain networks and a promising imaging biomarker. However, there is no established standard as to which method, modality, and analysis variant is preferable and there is only limited knowledge on the reproducibility, an important prerequisite for clinical application. We conducted an MEG-/ high-density (hd)-EEG-study on 22 young healthy adults, who were measured twice in a scan/rescan design after 7 – 2 days. Reliability of resting-state (15 min, eyes-closed) connectivity in source space was calculated via intraclass correlation coefficient (ICC) in classical frequency bands (delta-gamma). We investigated the reliability of two commonly used connectivity metrics, namely the imaginary part of coherency and the weighted phase-lag index and the influence of frequency band, vigilance, and the number of trials. We found a strong increase of reliability with more trials and relatively mild effects of vigilance. Reliability was excellent in the alpha band for MEG, as well as hd-EEG (ICC >0.85); in the theta band, reliability was good for MEG and poor for EEG. Other frequency bands showed lower reliability, with delta band being the worst. Furthermore, we investigated the spatial reliability of resting-state connectivity in a vertex-based approach, which reached fair to good reliability (ICC up to 0.67) with 5 min of data. Our results indicate that excellent reliability of global connectivity is achievable in alpha band, and vertex-based connectivity was still fair to good. Moreover, electrophysiological resting-state studies could benefit from more data than used previously. MEG and hd-EEG were similar in their overall performance but showed frequency band-specific differences.

year	journal	country	edition	language
2019-05-23	Brain Connectivity

https://doi.org/10.1089/brain.2019.0662