The multilayer network framework has emerged as an innovative approach for analyzing electrophysiological networks, providing insights into complex neuronal interactions by integrating connectivity across different frequency bands in electroencephalography (EEG) and magnetoencephalography (MEG) data.
Current Limitations:
Traditionally, multilayer networks have treated canonical frequency bands (e.g., delta, theta, alpha, beta, gamma) as distinct layers. Recent findings could raise potential concerns regarding this approach, emphasizing the need to incorporate the distinction between periodic (oscillatory) and aperiodic (broadband) signal components.
Conceptual Advance:
Aperiodic signals may reflect excitation–inhibition balance and scale-free dynamics, while periodic signals capture oscillatory rhythms, both contributing uniquely to brain network interactions. A multilayer network framework in the current context could be applicable in the case of genuine coupling between these components, termed “aperiodic-to-periodic coupling.” This necessitates novel connectivity metrics and analytical methods that can handle broadband data. Furthermore, challenges remain in decomposing these components in the time domain and developing robust metrics for broadband connectivity that account for signal leakage.
Outlook:
Addressing these issues will enhance multilayer frameworks, enabling better insights into brain network integrity, cognitive dysfunction, and neurological conditions.
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References
1.
BoccalettiS, BianconiG, CriadoR, et al.The structure and dynamics of multilayer networks. Phys Rep, 2014; 544(1):1–122.
2.
BrakeN, DucF, RokosA, et al.A neurophysiological basis for aperiodic EEG and the background spectral trend. Nat Commun, 2024; 15(1):1514.
3.
BreedtLC, SantosFAN, HillebrandA, et al.Multimodal multilayer network centrality relates to executive functioning. Netw Neurosci, 2023; 7(1):299–321.
4.
BrookesMJ, TewariePK, HuntBAE, et al.A multi-layer network approach to MEG connectivity analysis. Neuroimage, 2016; 132:425–438.
5.
CaiL, WeiX, LiuJ, et al.Functional integration and segregation in multiplex brain networks for Alzheimer’s disease. Front Neurosci, 2020; 14:51.
6.
ChaoulAI, SiegelM. Cortical correlation structure of aperiodic neuronal population activity. Neuroimage, 2021; 245:118672.
7.
DangW, LvD, RuiL, et al.Studying multi-frequency multilayer brain network via deep learning for EEG-based epilepsy detection. IEEE Sensors J, 2021; 21(24):27651–27658.
8.
De DomenicoM. Multilayer modeling and analysis of human brain networks. Gigascience, 2017; 6(5):1–8.
9.
DecoG, Sanz PerlY, BocaccioH, et al.The INSIDEOUT framework provides precise signatures of the balance of intrinsic and extrinsic dynamics in brain states. Commun Biol, 2022; 5(1):572.
10.
DonoghueT, HallerM, PetersonEJ, et al.Parameterizing neural power spectra into periodic and aperiodic components. Nat Neurosci, 2020; 23(12):1655–1665.
11.
DouQ, SongY, ZhangZ, et al.Differential evolution-based time domain decomposition method for multi-impact vibration signals of reciprocating machinery. Meas Sci Technol, 2024; 36(1):016148.
12.
Dupré la TourT, TallotL, GrabotL, et al.Non-linear auto-regressive models for cross-frequency coupling in neural time series. PLoS Comput Biol, 2017; 13(12):e1005893.
13.
EchegoyenI, López-SanzD, MaestúF, et al.From single layer to multilayer networks in mild cognitive impairment and Alzheimer’s disease. J Phys Complex, 2021; 2(4):045020.
14.
FreemanWJ. Origin, structure, and role of background EEG activity. Part 4: Neural frame simulation. Clin Neurophysiol, 2006; 117(3):572–589.
15.
GersterM, WaterstraatG, LitvakV, et al.Separating neural oscillations from aperiodic 1/f activity: Challenges and recommendations. Neuroinformatics, 2022; 20(4):991–1012.
16.
GuillonJ, AttalY, ColliotO, et al.Loss of brain inter-frequency hubs in Alzheimer’s disease. Sci Rep, 2017; 7(1):10879.
17.
HindriksR. Relation between the phase-lag index and lagged coherence for assessing interactions in EEG and MEG data. Neuroimage: Reports, 2021; 1(1):100007.
18.
HindriksR, BroedersTAA, SchoonheimMM, et al.Higher‐order functional connectivity analysis of resting‐state functional magnetic resonance imaging data using multivariate cumulants. Hum Brain Mapp, 2024a;45(5):e26663.
19.
HindriksR, RotTO, van PuttenMJAM, et al.2024b. Construction of invariant features for time-domain EEG/MEG signals using Grassmann manifolds. bioRxiv 2023–2024.
KaraaslanliA, Ortiz-BouzaM, MuniaTTK, et al.Community detection in multi-frequency EEG networks. Sci Rep, 2023; 13(1):8114.
22.
KlugerDS, ForsterC, AbbasiO, et al.Modulatory dynamics of periodic and aperiodic activity in respiration-brain coupling. Nat Commun, 2023; 14(1):4699.
23.
MandkeK, MeierJ, BrookesMJ, et al.Comparing multilayer brain networks between groups: Introducing graph metrics and recommendations. Neuroimage, 2018; 166:371–384; doi: 10.1016/j.neuroimage.2017.11.016
24.
MitraA, SnyderAZ, BlazeyT, et al.Lag threads organize the brain’s intrinsic activity. Proc Natl Acad Sci U S A, 2015; 112(17):E2235–E2244.
25.
MuthukumaraswamySD, LileyDTJ. 1/f electrophysiological spectra in resting and drug-induced states can be explained by the dynamics of multiple oscillatory relaxation processes. Neuroimage, 2018; 179:582–595.
26.
NandaA, JohnsonGW, MuY, et al.Time-resolved correlation of distributed brain activity tracks EI balance and accounts for diverse scale-free phenomena. Cell Rep, 2023; 42(4):112254.
27.
NolteG, BaiO, WheatonL, et al.Identifying true brain interaction from EEG data using the imaginary part of coherency. Clin Neurophysiol, 2004; 115(10):2292–2307.
28.
NugentAC, BallardED, GilbertJR, et al.Multilayer MEG functional connectivity as a potential marker for suicidal thoughts in major depressive disorder. Neuroimage Clin, 2020a;28:102378.
29.
NugentAC, BallardED, GilbertJR, et al.The effect of ketamine on electrophysiological connectivity in major depressive disorder. Front Psychiatry, 2020b;11:519; doi: 10.3389/fpsyt.2020.00519
30.
PalPK, AnwarMS, PercM, et al.Global synchronization in generalized multilayer higher-order networks. Phys Rev Res, 2024; 6:033003.
31.
PourdavoodP, JacobM. EEG spectral attractors identify a geometric core of brain dynamics. Patterns, 2024; 5(9):101025.
32.
PuxedduMG, PettiM, AstolfiL. A comprehensive analysis of multilayer community detection algorithms for application to EEG-based brain networks. Front Syst Neurosci, 2021; 15:624183.
33.
StamCJ, NolteG, DaffertshoferA. Phase lag index: Assessment of functional connectivity from multi channel EEG and MEG with diminished bias from common sources. Hum Brain Mapp, 2007; 28(11):1178–1193.
34.
TewarieP, HillebrandA, van DijkBW, et al.Integrating cross-frequency and within band functional networks in resting-state MEG: A multi-layer network approach. Neuroimage, 2016; 142:324–336; doi: 10.1016/j.neuroimage.2016.07.057
35.
TewariePKB, HindriksR, LaiYM, et al.Non-reversibility outperforms functional connectivity in characterisation of brain states in MEG data. Neuroimage, 2023; 276:120186.
36.
TewarieP, PrasseB, MeierJ, et al.Interlayer connectivity reconstruction for multilayer brain networks using phase oscillator models. New J Phys, 2021; 23(6):063065; doi: 10.1088/1367-2630/ac066d
van LingenMR, BreedtLC, GeurtsJJG, et al.The longitudinal relation between executive functioning and multilayer network topology in glioma patients. Brain Imaging Behav, 2023; 17(4):425–435.
39.
WenH, LiuZ. Separating fractal and oscillatory components in the power spectrum of neurophysiological signal. Brain Topogr, 2016; 29(1):13–26.
40.
YuM, EngelsMM, HillebrandA, et al.Selective impairment of hippocampus and posterior hub areas in Alzheimer’s disease: An MEG-based multiplex network study. Brain, 2017; 140(5):1466–1485.
