Sage Journals: Discover world-class research

Abstract

Background:

Brain imaging data collected from individuals are highly complex with unique variation; however, such variation is typically ignored in approaches that focus on group averages or even supervised prediction. State-of-the-art methods for analyzing dynamic functional network connectivity (dFNC) subdivide the entire time course into several (possibly overlapping) connectivity states (i.e., sliding window clusters). However, such an approach does not factor in the homogeneity of underlying data and may result in a less meaningful subgrouping of the data set.

Methods:

Dynamic-N-way tri-clustering (dNTiC) incorporates a homogeneity benchmark to approximate clusters that provide a more “apples-to-apples” comparison between groups within analogous subsets of time-space and subjects. dNTiC sorts the dFNC states by maximizing similarity across individuals and minimizing variance among the pairs of components within a state.

Results:

Resulting tri-clusters show significant differences between schizophrenia (SZ) and healthy control (HC) in distinct brain regions. Compared with HC subjects, SZ show hypoconnectivity (low positive) among subcortical, default mode, cognitive control, but hyperconnectivity (high positive) between sensory networks in most tri-clusters. In tri-cluster 3, HC subjects show significantly stronger connectivity among sensory networks and anticorrelation between subcortical and sensory networks than SZ. Results also provide a statistically significant difference in SZ and HC subject's reoccurrence time for two distinct dFNC states.

Conclusions:

Outcomes emphasize the utility of the proposed method for characterizing and leveraging variance within high-dimensional data to enhance the interpretability and sensitivity of measurements in studying a heterogeneous disorder such as SZ and unconstrained experimental conditions as resting functional magnetic resonance imaging.

Impact statement

The current methods for analyzing dynamic functional network connectivity (dFNC) run k-means on a collection of dFNC windows, and each window includes all the pairs of independent component analysis networks. As such, it depicts a short-time connectivity pattern of the entire brain, and the k-means clusters fixed-length signatures that have an extent throughout the neural system. Consequently, there is a chance of missing connectivity signatures that span across a smaller subset of pairs. Dynamic-N-way tri-clustering further sorts the dFNC states by maximizing similarity across individuals, minimizing variance among the pairs of components within a state, and reporting more complex and transient patterns.

Get full access to this article

View all access options for this article.

References

Abrol

, Damaraju

, Miller

, et al. 2017. Replicability of time-varying connectivity patterns in large resting state fMRI samples. NeuroImage, 163:160–176.

Allen

, Damaraju

, Plis

, et al. 2014. Tracking whole-brain connectivity dynamics in the resting state. Cereb Cortex, 24:663–676.

Allen

, Erhardt

, Damaraju

, et al. 2011. A baseline for the multivariate comparison of resting-state networks. Front Syst Neurosci, 5:2.

Alnæs

, Kaufmann

, van der Meer

, et al. 2019. Brain heterogeneity in schizophrenia and its association with polygenic risk. JAMA Psychiatry, 76:739–748.

Arieli

, Sterkin

, Grinvald

, et al. 1996. Dynamics of ongoing activity: explanation of the large variability in evoked cortical responses. Science, 273:1868–1871.

Barber

, Lindquist

, DeRosse

, et al. 2018. Dynamic functional connectivity states reflecting psychotic-like experiences. Biol Psychiatry Cogn Neurosci Neuroimaging, 3:443–453.

Beckmann

, DeLuca

, Devlin

, et al. 2005. Investigations into resting-state connectivity using independent component analysis. Philos Trans R Soc Lond B Biol Sci, 360:1001–1013.

Calhoun

, Adali

, Pearlson

, et al. 2001. A method for making group inferences from functional MRI data using independent component analysis. Hum Brain Mapp, 14:140–151.

Calhoun

, Kiehl

, Pearlson

. 2008. Modulation of temporally coherent brain networks estimated using ICA at rest and during cognitive tasks. Hum Brain Mapp, 29:828–838.

10.

Cetin

, Houck

, Rashid

, et al. 2016. Multimodal classification of schizophrenia patients with MEG and fMRI data using static and dynamic connectivity measures. Front Neurosci, 10:466.

11.

Damaraju

, Allen

, Belger

, et al. 2014. Dynamic functional connectivity analysis reveals transient states of dysconnectivity in schizophrenia. Neuroimage Clin, 5:298–308.

12.

Damoiseaux

, Rombouts

, Barkhof

, et al. 2006. Consistent resting-state networks across healthy subjects. Proc Natl Acad Sci U S A, 103:13848–13853.

13.

, Fu

, Sui

, et al. 2020. NeuroMark: an adaptive independent component analysis framework for estimating reproducible and comparable fMRI biomarkers among brain disorders. Neuroimage Clin, 28:102375.

14.

, Pearlson

, Lin

, et al. 2017. Identifying dynamic functional connectivity biomarkers using GIG-ICA: application to schizophrenia, schizoaffective disorder, and psychotic bipolar disorder. Hum Brain Mapp, 38:2683–2708.

15.

Erhardt

, Rachakonda

, Bedrick

, et al. 2011. Comparison of multi-subject ICA methods for analysis of fMRI data. Hum Brain Mapp, 32:2075–2095.

16.

Even

. 2011. Depth-first search. In: Even G (ed.) Graph Algorithms. Cambridge: Cambridge University Press; pp. 46–64.

17.

Ferri

, Ford

, Roach

, et al. 2018. Resting-state thalamic dysconnectivity in schizophrenia and relationships with symptoms. Psychol Med, 48:2492–2499.

18.

Franco

, Pritchard

, Calhoun

, et al. 2009. Interrater and intermethod reliability of default mode network selection. Hum Brain Mapp, 30:2293–2303.

19.

Friedman

, Hastie

, Tibshirani

. 2008. Sparse inverse covariance estimation with the graphical lasso. Biostatistics, 9:432–441.

20.

, Tu

, Di

, et al. 2018. Characterizing dynamic amplitude of low-frequency fluctuation and its relationship with dynamic functional connectivity: an application to schizophrenia. NeuroImage, 180:619–631.

21.

Hindriks

, Adhikari

, Murayama

, et al. 2016. Can sliding-window correlations reveal dynamic functional connectivity in resting-state fMRI?. NeuroImage, 127:242–256.

22.

Hripcsak

, Rothschild

. 2005. Agreement, the f-measure, and reliability in information retrieval. J Am Med Inform Assoc, 12:296–298.

23.

Ioannides

. 2007. Dynamic functional connectivity. Curr Opin Neurobiol, 17:161–170.

24.

Javitt

, Sweet

. 2015. Auditory dysfunction in schizophrenia: integrating clinical and basic features. Nat Rev Neurosci, 16:535–550.

25.

Kay

, Fiszbein

, Opler

. 1987. The positive and negative syndrome scale (PANSS) for schizophrenia. Schizophr Bull, 13:261–276.

26.

Keator

, van Erp

TGM

, Turner

, et al. 2016. The function biomedical informatics research network data repository. Neuroimage, 124(Pt B):1074–1079.

27.

Klugah-Brown

, Luo

, He

, et al. 2019. Altered dynamic functional network connectivity in frontal lobe epilepsy. Brain Topogr, 32:394–404.

28.

Kozen

. 1992. Depth-first and breadth-first search. In: Gries D (ed.) The Design and Analysis of Algorithms. New York, NY: Springer; pp. 19–24.

29.

Kucyi

, Davis

. 2014. Dynamic functional connectivity of the default mode network tracks daydreaming. NeuroImage, 100:471–480.

30.

Lawrie

, Abukmeil

. 1998. Brain abnormality in schizophrenia: a systematic and quantitative review of volumetric magnetic resonance imaging studies. Br J Psychiatry, 172:110–120.

31.

Leonardi

, Van De Ville

. 2015. On spurious and real fluctuations of dynamic functional connectivity during rest. NeuroImage, 104:430–436.

32.

, Zhang

, Liang

, et al. 2017. High transition frequencies of dynamic functional connectivity states in the creative brain. Sci Rep, 7:46072.

33.

, Calhoun

, Phlypo

, et al. 2014. Dynamic changes of spatial functional network connectivity in healthy individuals and schizophrenia patients using independent vector analysis. NeuroImage, 90:196–206.

34.

Makeig

, Debener

, Onton

, et al. 2004. Mining event-related brain dynamics. Trends Cogn Sci, 8:204–210.

35.

Miller

, Yaesoubi

, Turner

, et al. 2016. Higher dimensional meta-state analysis reveals reduced resting fMRI connectivity dynamism in schizophrenia patients. PLoS One, 11:e0149849.

36.

Onton

, Westerfield

, Townsend

, et al. 2006. Imaging human EEG dynamics using independent component analysis. Neurosci Biobehav Rev, 30:808–822.

37.

Rabinowicz

, Silipo

, Goldman

, et al. 2000. Auditory sensory dysfunction in schizophrenia: imprecision or distractibility?. Arch Gen Psychiatry, 57:1149–1155.

38.

Rahaman

, Turner

, Gupta

, et al. 2020. N-BiC: a method for multi-component and symptom biclustering of structural MRI data: application to schizophrenia. IEEE Trans Biomed Eng, 67:110–121.

39.

Rashid

, Arbabshirani

, Damaraju

, et al. 2016. Classification of schizophrenia and bipolar patients using static and dynamic resting-state fMRI brain connectivity. Neuroimage, 134:645–657.

40.

Rashid

, Chen

, Rashid

, et al. 2019. A framework for linking resting-state chronnectome/genome features in schizophrenia: a pilot study. Neuroimage, 184:843–854.

41.

Rashid

, Damaraju

, Pearlson

, et al. 2014. Dynamic connectivity states estimated from resting fMRI Identify differences among schizophrenia, bipolar disorder, and healthy control subjects. Front Hum Neurosci, 8:897.

42.

Saha

, Abrol

, Damaraju

, et al. 2019. Classification as a criterion to select model order for dynamic functional connectivity states in rest-fMRI data. In: 2019 IEEE 16th International Symposium on Biomedical Imaging (ISBI 2019). Venice, Italy: IEEE. DOI: 10.1109/ISBI.2019.8759146.

43.

Sakoglu

, Michael

, Calhoun

. 2009. Classification of schizophrenia patients vs healthy controls with dynamic functional network connectivity. Neuroimage, 47:S39–S41.

44.

Santamaría

, Quintales

, Therón

. 2007. Methods to bicluster validation and comparison in microarray data. In: Yin H, Tino P, Corchado E, Byrne W, Yao X (eds.) International Conference on Intelligent Data Engineering and Automated Learning. Heidelberg, Germany: Springer; pp. 780–789.

45.

Shakil

, Lee

C-H

, Keilholz

. 2016. Evaluation of sliding window correlation performance for characterizing dynamic functional connectivity and brain states. NeuroImage, 133:111–128.

46.

Shehzad

, Kelly

, Reiss

, et al. 2009. The resting brain: unconstrained yet reliable. Cereb Cortex, 19:2209–2229.

47.

Smith

, Miller

, Salimi-Khorshidi

, et al. 2011. Network modelling methods for FMRI. NeuroImage, 54:875–891.

48.

Tsuang

, Lyons

, Faraone

. 1990. Heterogeneity of schizophrenia: conceptual models and analytic strategies. Br J Psychiatry, 156:17–26.

49.

Turner

, Damaraju

, Van Erp

, et al. 2013. A multi-site resting state fMRI study on the amplitude of low frequency fluctuations in schizophrenia. Front Neurosci, 7:137.

50.

Varoquaux

, Gramfort

, Poline

J-B

, et al. 2010. Brain covariance selection: better individual functional connectivity models using population prior. Adv Neural Inf Process Syst, 23:2334–2342.

51.

Vergara

, Mayer

, Kiehl

, et al. 2018. Dynamic functional network connectivity discriminates mild traumatic brain injury through machine learning. NeuroImage Clin, 19:30–37.

52.

Wang

, Wang

, Huang

, et al. 2020. Abnormal dynamic functional network connectivity in unmedicated bipolar and major depressive disorders based on the triple-network model. Psychol Med, 50:465–474.

53.

Zisook

, McAdams

, Kuck

, et al. 1999. Depressive symptoms in schizophrenia. Am J Psychiatry, 156:1736–1743.

54.

Zuo

, Di Martino

, Kelly

, et al. 2010. The oscillating brain: complex and reliable. Neuroimage, 49:1432–1445.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.56 MB

0.00 MB

Tri-Clustering Dynamic Functional Network Connectivity Identifies Significant Schizophrenia Effects Across Multiple States in Distinct Subgroups of Individuals

Abstract

Background:

Methods:

Results:

Conclusions:

Impact statement

Get full access to this article

References

Supplementary Material