Studies of resting-state fMRI have shown that blood oxygen level dependent (BOLD) signals giving rise to temporal correlation across voxels (or regions) are dominated by low-frequency fluctuations in the range of ∼0.01–0.1 Hz. These low-frequency fluctuations have been further divided into multiple distinct frequency bands (slow-5 and -4) based on earlier neurophysiological studies, though low sampling frequency of fMRI (∼0.5 Hz) has substantially limited the exploration of other known frequency bands of neurophysiological origins (slow-3, -2, and -1). In this study, we used resting-state fMRI data acquired from 21 healthy subjects at a higher sampling frequency of 1.5 Hz to assess the presence of resting-state functional connectivity (RSFC) across multiple frequency bands: slow-5 to slow-1. The effect of different frequency bands on spatial extent and connectivity strength for known resting-state networks (RSNs) was also evaluated. RSNs were derived using independent component analysis and seed-based correlation. Commonly known RSNs, such as the default mode, the fronto-parietal, the dorsal attention, and the visual networks, were consistently observed at multiple frequency bands. Significant inter-hemispheric connectivity was observed between each seed and its contra lateral brain region across all frequency bands, though overall spatial extent of seed-based correlation maps decreased in slow-2 and slow-1 frequency bands. These results suggest that functional integration between brain regions at rest occurs over multiple frequency bands and RSFC is a multiband phenomenon. These results also suggest that further investigation of BOLD signal in multiple frequency bands for related cognitive processes should be undertaken.
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References
1.
BabiloniF, CincottiF, BabiloniC, CarducciF, MattiaD, AstolfiL, HeB. 2005. Estimation of the cortical functional connectivity with the multimodal integration of high-resolution EEG and fMRI data by directed transfer function. Neuroimage, 24:118–131.
2.
BeckmannCF, DeLucaM, DevlinJT, SmithSM. 2005. Investigations into resting-state connectivity using independent component analysis. Philos Trans R Soc Lond B Biol Sci, 360:1001–1013.
3.
BehzadiY, RestomK, LiauJ, LiuTT. 2007. A component based noise correction method (CompCor) for BOLD and perfusion based fMRI. Neuroimage, 37:90–101.
4.
BirnR, DiamondJB, SmithMA, BandettiniPA. 2006. Separating respiratory-variation-related fluctuations from neuronal-activity-related fluctuations in fMRI. Neuroimage, 31:1536–1548.
BiswalBB, ZerrinYF, HaughtonVM, HydeJS. 1995. Functional connectivity in the motor cortex of resting human brain using echo-planar mri. Magn Reson Med, 34:537–541.
7.
BoubelaRN, KalcherK, HufW, KronnerwetterC, FilzmoserP, MoserE. 2013. Beyond noise: using temporal ICA to extract meaningful information from high-frequency fMRI signal fluctuations during rest. Front Hum Neurosci, 7:168.
8.
BrookesMJ, WoolrichM, LuckhooH, PriceD, HaleJR, StephensonMC, BarnesGR, SmithSM, MorrisPG. 2011. Investigating the electrophysiological basis of resting state networks using magnetoencephalography. Proc Natl Acad Sci U S A, 108:16783–16788.
9.
BuzsákiG, DraguhnA. 2004. Neuronal oscillations in cortical networks. Science, 304:1926–1929.
10.
ChaiXJ, CastanonAN, OngurD, Whitfield-GabrieliS. 2012. Anticorrelations in resting state networks without global signal regression. Neuroimage, 59:1420–1428.
11.
CordesD, HaughtonVM, ArfanakisK, CarewJD, TurskiPA, MoritzCH, QuigleyMA, MeyerandME. 2001. Frequencies contributing to functional connectivity in the cerebral cortex in “resting-state” data. AJNR Am J Neuroradiol, 22:1326–1333.
12.
CoxRW. 1996. AFNI: software for analysis and visualization of functional magnetic resonance neuroimages. Comput Biomed Res., 29:162–173.
13.
FeinbergDA, MoellerS, SmithSM, AuerbachE, RamannaS, GuntherM, GlasserMF, MillerKL, UgurbilK, YacoubE. 2010. Multiplexed echo planar imaging for sub-second whole brain FMRI and fast diffusion imaging. PLoS One, 5:e15710.
14.
FeinbergDA, YacoubE. 2012. The rapid development of high speed, resolution and precision in fMRI. Neuroimage, 62:720–725.
15.
FoxMD, SnyderAZ, VincentJL, CorbettaM, Van EssenDC, RaichleME. 2005. The human brain is intrinsically organized into dynamic, anticorrelated functional networks. Proc Natl Acad Sci U S A, 102:9673–9678.
16.
FristonKJ, FrithCD, LiddlePF, FrackowiakRS. 1993. Functional connectivity: the principal-component analysis of large (PET) data sets. J Cereb Blood Flow Metab, 13:5–1.
17.
GloverGH, LiTQ, RessD. 2000. Image-based method for retrospective correction of physiological motion effects in fMRI: RETROICOR. Magn Reson Med, 44:162–167.
18.
GreiciusMD, SupekarK, MenonV, DoughertyRF. 2009. Resting-state functional connectivity reflects structural connectivity in the default mode network. Cereb Cortex, 19:72–78.
19.
LuH, ZouQ, GuH, RaichleME, SteinEA, YangY. 2012. Rat brains also have a default mode network. Proc Natl Acad Sci U S A, 109:3979–3984.
20.
HelpsS, JamesC, DebenerS, KarlA, Sonuga-BarkeEJ. 2008. Very low frequency EEG oscillations and the resting brain in young adults: a preliminary study of localisation, stability and association with symptoms of inattention. J Neural Transm, 115:279–285.
21.
HelpsSK, BroydSJ, JamesCJ, KarlA, Sonuga-BarkeEJ. 2009. The attenuation of very low frequency brain oscillations in transitions from a rest state to active attention. J Psychophysiol, 23:191–198.
22.
HorwitzB, DuaraR, RapoportSI. 1984. Intercorrelations of glucose metabolic rates between brain regions: application to healthy males in a state of reduced sensory input. J Cereb Blood Flow Metab, 4:484–499.
23.
HydeJ, BiswalB, JesmanowiczA. 2001. High resolution fMRI using multislice partial k-space GR-EPI with cubic voxels. Magn Reson Med, 46:114–125.
24.
JesmanowiczA, NenckaAS, LiSJ, HydeJS. 2011. Two-axis acceleration of functional connectivity magnetic resonance imaging by parallel excitation of phase-tagged slices and half k-space acceleration. Brain Connect, 1:81–90.
25.
JonckersE, Van AudekerkeJ, De VisscherG, Van der LindenA, VerhoyeM. 2011. Functional connectivity fMRI of the rodent brain: comparison of functional connectivity networks in rat and mouse. PLoS One, 6:e18876.
26.
KannurpattiS, BiswalB, KimY, RosenB. 2008. Spatio-temporal characteristics of low-frequency BOLD signal fluctuations in isoflurane-anesthetized rat brain. Neuroimage, 40:1738–1747.
27.
KellerCJ, BickelS, HoneyCJ, GroppeDM, EntzL, CraddockRC, LadoFA, KellyC, MilhamM, MehtaAD. 2013. Neurophysiological investigation of spontaneous correlated and anticorrelated fluctuations of the BOLD signal. J Neurosci, 33:6333–6342.
28.
KiviniemiV, KantolaJH, JauhiainenJ, HyvärinenA, TervonenO. 2003. Independent component analysis of nondeterministic fMRI signal sources. Neuroimage, 19(2 Pt 1):253–260.
29.
LaufsH, HoltJL, ElfontR, KramsM, PaulJS, KrakowK, KleinschmidtA. 2006. Where the BOLD signal goes when alpha EEG leaves. Neuroimage, 31:1408–1418.
30.
LeeHL, ZahneisenB, HuggerT, LeVanP, HennigJ. 2012. Tracking dynamic resting-state networks at higher frequencies using MR-encephalography. Neuroimage, 65:216–222.
31.
LiaoW, ZhangZ, MantiniD, XuQ, WangZ, ChenG, JiaoQ, ZangYF, LuG. 2013. Relationship between large-scale functional and structural covariance networks in idiopathic generalized epilepsy. Brain Connect, 3:240–254.
32.
LlinasRR. 1988. The intrinsic electrophysiological properties of mammalian neurons: insights into central nervous system function. Science, 242:1654–1664.
33.
LogothetisNK, PaulsJ, AugathM, TrinathT, OeltermannA. 2001. Neurophysiological investigation of the basis of the fMRI signal. Nature, 412:150–157.
34.
MantiniD, PerrucciMG, Del GrattaC, RomaniGL, CorbettaM. 2007. Electrophysiological signatures of resting state networks in the human brain. Proc Natl Acad Sci U S A, 104:13170–13175.
35.
MazaheriY, BiswalB, WardB, HydeJ. 2006. Measurements of tissue T spin-lattice relaxation time and discrimination of large draining veins using transient EPI data sets in BOLD-weighted fMRI acquisitions. Neuroimage, 32:603–615.
36.
MeyerMC, JanssenRJ, Van OortES, BeckmannCF, BarthM. 2013. The quest for EEG power band correlation with ICA derived fMRI resting state networks. Front Hum Neurosci, 7:315.
37.
MussoF, BrinkmeyerJ, MobascherA, WarbrickT, WintererG. 2010. Spontaneous brain activity and EEG microstates. A novel EEG/fMRI analysis approach to explore resting-state networks. Neuroimage, 52:1149–1161.
38.
NiazyRK, XieJ, MillerK, BeckmannCF, SmithSM. 2011. Spectral characteristics of resting state networks. Prog Brain Res, 193:259–276.
39.
NoonerKB, ColcombeSJ, TobeRH, MennesM, BenedictMM, MorenoAL, PanekLJ, BrownS, ZavitzST, LiQ, SikkaS, GutmanD, BangaruS, SchlachterRT, KamielSM, AnwarAR, HinzCM, KaplanMS, RachlinAB, AdelsbergS, CheungB, KhanujaR, YanC, CraddockCC, CalhounV, CourtneyW, KingM, WoodD, CoxCL, KellyAM, Di MartinoA, PetkovaE, ReissPT, DuanN, ThomsenD, BiswalB, CoffeyB, HoptmanMJ, JavittDC, PomaraN, SidtisJJ, KoplewiczHS, CastellanosFX, LeventhalBL, MilhamMP. 2012. The NKI-Rockland sample: a model for accelerating the pace of discovery science in psychiatry. Front Neurosci, 6:152.
40.
PawelaC, BiswalB, ChoY, KaoD, LiR, JonesS, HydeJ. 2008. Resting-state functional connectivity of the rat brain. Magn Reson Med, 59:1021–1029.
SaadZS, GottsSJ, MurphyK, ChenG, JoHJ, MartinA, CoxRW. 2012. Trouble at rest: how correlation patterns and group differences become distorted after global signal regression. Brain Connect, 2:25–32.
