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Abstract

Background/Purpose:

To investigate the association between the degree of spatial neglect and the changes of brain system segregation (SyS; i.e., the ratio of the extent to which brain networks interact internally and with each other) after stroke.

Methods:

A cohort of 20 patients with right hemisphere lesion was submitted to neuropsychological assessment as well as to resting-state functional magnetic resonance imaging session at acute stage after stroke. The severity of spatial neglect was quantified using the Center of Cancellation (CoC) scores of the Bells cancellation test. For each patient, resting-state functional connectivity (FC) matrices were assessed by implementing a brain parcellation of nine networks that included the visual network, dorsal attention network (DAN), ventral attention network (VAN), sensorimotor network (SMN), auditory network, cingulo-opercular network, language network, frontoparietal network, and default mode network (DMN). For each patient and each network, we then computed the SyS derived by subtracting the between-network FC from the within-network FC (normalized by the within-network FC). Finally, for each network, the CoC scores were correlated with the SyS.

Results:

The correlational analyses indicated a negative association between CoC and SyS in the DAN, VAN, SMN, and DMN (q < 0.05 false discovery rate [FDR]-corrected). Patients with more severe spatial neglect exhibited lower SyS and vice versa.

Conclusion:

The loss of segregation in multiple and specific networks provides a functional framework for the deficits in spatial and nonspatial attention and motor/exploratory ability observed in neglect patients.

Impact statement

In a graph-theoretic framework, we identify a loss of system segregation associative and sensorimotor networks in neglect patients who had suffered from right hemisphere stroke. From a theoretical standpoint, our findings corroborate the working hypothesis that the efficient segregation among brain systems is relevant for executing higher functions such as spatial attention. Clinically, the set of networks that exhibit loss of segregation offers a therapeutic opportunity and can be targets of neuromodulation protocols for neglect rehabilitation.

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References

Arnemann

, Chen

, Novakovic-Agopian

, et al. 2015. Functional brain network modularity predicts response to cognitive training after brain injury. Neurology, 84:1568–1574.

Baldassarre

, Metcalf

, Shulman

, et al. 2019. Brain networks' functional connectivity separates aphasic deficits in stroke. Neurology, 92:e125–e135.

Baldassarre

, Ramsey

, Hacker

, et al. 2014. Large-scale changes in network interactions as a physiological signature of spatial neglect. Brain, 137:3267–3283.

Baldassarre

, Ramsey

, Rengachary

, et al. 2016a. Dissociated functional connectivity profiles for motor and attention deficits in acute right-hemisphere stroke. Brain, 139:2024–2038.

Baldassarre

, Ramsey

, Siegel

, et al. 2016b. Brain connectivity and neurological disorders after stroke. Curr Opin Neurol, 29:706–713.

Barrett

, Boukrina

, Saleh

. 2019. Ventral attention and motor network connectivity is relevant to functional impairment in spatial neglect after right brain stroke. Brain Cogn, 129:16–24.

Bauer

, Kraft

, Wright

, et al. 2014. Optical imaging of disrupted functional connectivity following ischemic stroke in mice. Neuroimage, 99:388–401.

Benjamini

, Hochberg

. 1995. Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc Ser B, 57:289–300.

Binder

, Marshall

, Lazar

, et al. 1992. Distinct syndromes of hemineglect. Arch Neurol, 49:1187–1194.

10.

Biswal

, Yetkin

, Haughton

, et al. 1995. Functional connectivity in the motor cortex of resting human brain using echo-planar MRI. Magn Reson Med, 34:537–541.

11.

Boly

, Phillips

, Tshibanda

, et al. 2008. Intrinsic brain activity in altered states of consciousness: how conscious is the default mode of brain function?. Ann N Y Acad Sci, 1129:119–129.

12.

Brier

, Thomas

, Fagan

, et al. 2014. Functional connectivity and graph theory in preclinical Alzheimer's disease. Neurobiol Aging, 35:757–768.

13.

Buckner

, Andrews-Hanna

, Schacter

. 2008. The brain's default network: anatomy, function, and relevance to disease. Ann N Y Acad Sci, 1124:1–38.

14.

Buckner

, Sepulcre

, Talukdar

, et al. 2009. Cortical hubs revealed by intrinsic functional connectivity: mapping, assessment of stability, and relation to Alzheimer's disease. J Neurosci, 29:1860–1873.

15.

Carrera

, Tononi

. 2014. Diaschisis: past, present, future. Brain, 137:2408–2422.

16.

Carter

, Astafiev

, Lang

, et al. 2010. Resting interhemispheric functional magnetic resonance imaging connectivity predicts performance after stroke. Ann Neurol, 67:365–375.

17.

Chan

, Park

, Savalia

, et al. 2014. Decreased segregation of brain systems across the healthy adult lifespan. Proc Natl Acad Sci U S A, 111:E4997–E5006.

18.

Corbetta

, Kincade

, Lewis

, et al. 2005. Neural basis and recovery of spatial attention deficits in spatial neglect. Nat Neurosci, 8:1603–1610.

19.

Corbetta

, Shulman

. 2002. Control of goal-directed and stimulus-driven attention in the brain. Nat Rev Neurosci, 3:201–215.

20.

Corbetta

, Shulman

. 2011. Spatial neglect and attention networks. Annu Rev Neurosci, 34:569–599.

21.

Croce

, Spadone

, Zappasodi

, et al. 2021. rTMS affects EEG microstates dynamic during evoked activity. Cortex, 138:302–310.

22.

de Pasquale

, Chiacchiaretta

, Pavone

, et al. 2023. Brain topological reorganization associated with visual neglect after stroke. Brain Connect, 13:473–486.

23.

de Pasquale

, Della Penna

, Snyder

, et al. 2010. Temporal dynamics of spontaneous MEG activity in brain networks. Proc Natl Acad Sci U S A, 107:6040–6045.

24.

de Pasquale

, Della Penna

, Snyder

, et al. 2012. A cortical core for dynamic integration of functional networks in the resting human brain. Neuron, 74:753–764.

25.

Ewers

, Luan

, Frontzkowski

, et al. 2021. Segregation of functional networks is associated with cognitive resilience in Alzheimer's disease. Brain, 144:2176–2185.

26.

Finger

, Koehler

, Jagella

. 2004. The Monakow concept of diaschisis: origins and perspectives. Arch Neurol, 61:283–288.

27.

Fox

, Raichle

. 2007. Spontaneous fluctuations in brain activity observed with functional magnetic resonance imaging. Nat Rev Neurosci, 8:700–711.

28.

Fox

, Zhang

, Snyder

, et al. 2009. The global signal and observed anticorrelated resting state brain networks. J Neurophysiol, 101:3270–3283.

29.

Gallen

, Baniqued

, Chapman

, et al. 2016. Modular brain network organization predicts response to cognitive training in older adults. PLoS One, 11:e0169015.

30.

Gilbert

, Dumontheil

, Simons

, et al. 2007. Comment on “Wandering minds: the default network and stimulus-independent thought.”. Science, 317:43; author reply 43.

31.

Gordon

, Laumann

, Adeyemo

, et al. 2016. Generation and evaluation of a cortical area parcellation from resting-state correlations. Cereb Cortex, 26:288–303.

32.

Gordon

, Lynch

, Gratton

, et al. 2018. Three distinct sets of connector hubs integrate human brain function. Cell Rep, 24:1687.e4–1695.e4.

33.

Gusnard

, Raichle

. 2001. Searching for a baseline: functional imaging and the resting human brain. Nat Rev Neurosci, 2:685–694.

34.

Hacker

, Laumann

, Szrama

, et al. 2013. Resting-state network estimation in individual subjects. Neuroimage, 82:616–633.

35.

Halligan

, Marshall

, Wade

. 1989. Visuospatial neglect: underlying factors and test sensitivity. Lancet, 2:908–911.

36.

Hampson

, Driesen

, Skudlarski

, et al. 2006. Brain connectivity related to working memory performance. J Neurosci, 26:13338–13343.

37.

, Snyder

, Vincent

, et al. 2007. Breakdown of functional connectivity in frontoparietal networks underlies behavioral deficits in spatial neglect. Neuron, 53:905–918.

38.

Heilman

, Watson

. 1977. The neglect syndrome—a unilateral defect of the orienting response. In: Harnad

, Doty

, Goldstein

, et al. (eds.) Lateralization in the Nervous System. New York, NY: Academic Press; pp. 285–302.

39.

Klingbeil

, Wawrzyniak

, Stockert

, et al. 2019. Resting-state functional connectivity: an emerging method for the study of language networks in post-stroke aphasia. Brain Cogn, 131:22–33.

40.

Malagurski

, Liem

, Oschwald

, et al. 2020. Functional dedifferentiation of associative resting state networks in older adults—a longitudinal study. Neuroimage, 214:116680.

41.

Marek

, Hwang

, Foran

, et al. 2015. The contribution of network organization and integration to the development of cognitive control. PLoS Biol, 13:e1002328.

42.

Pedersen

, Geerligs

, Andersson

, et al. 2021. When functional blurring becomes deleterious: reduced system segregation is associated with less white matter integrity and cognitive decline in aging. Neuroimage, 242:118449.

43.

Power

, Barnes

, Snyder

, et al. 2012. Spurious but systematic correlations in functional connectivity MRI networks arise from subject motion. Neuroimage, 59:2142–2154.

44.

Power

, Cohen

, Nelson

, et al. 2011. Functional network organization of the human brain. Neuron, 72:665–678.

45.

Rehme

, Volz

, Feis

, et al. 2015. Identifying neuroimaging markers of motor disability in acute stroke by machine learning techniques. Cereb Cortex, 25:3046–3056.

46.

Robertson

, Tegner

, Tham

, et al. 1995. Sustained attention training for unilateral neglect: theoretical and rehabilitation implications. J Clin Exp Neuropsychol, 17:416–430.

47.

Rorden

, Karnath

. 2010. A simple measure of neglect severity. Neuropsychologia, 48:2758–2763.

48.

Rubinov

, Sporns

. 2010. Complex network measures of brain connectivity: uses and interpretations. Neuroimage, 52:1059–1069.

49.

Sebastiani

, Chiacchiaretta

, Pavone

, et al. 2021. Cortical hyper-connectivity in a stroke patient with rotated drawing. Case Rep Neurol, 13:677–686.

50.

Shulman

, Fiez

, Corbetta

, et al. 1997. Common blood flow changes across visual tasks: II. decreases in cerebral cortex. J Cogn Neurosci, 9:648–663.

51.

Siegel

, Ramsey

, Snyder

, et al. 2016. Disruptions of network connectivity predict impairment in multiple behavioral domains after stroke. Proc Natl Acad Sci U S A, 113:E4367–E4376.

52.

Siegel

, Seitzman

, Ramsey

, et al. 2018. Re-emergence of modular brain networks in stroke recovery. Cortex, 101:44–59.

53.

Spadone

, Sestieri

, Baldassarre

, et al. 2017. Temporal dynamics of TMS interference over preparatory alpha activity during semantic decisions. Sci Rep, 7:2372.

54.

Tononi

, Sporns

, Edelman

. 1994. A measure for brain complexity: relating functional segregation and integration in the nervous system. Proc Natl Acad Sci U S A, 91:5033–5037.

55.

Vogt

, Laureys

. 2005. Posterior cingulate, precuneal and retrosplenial cortices: cytology and components of the neural network correlates of consciousness. Prog Brain Res, 150:205–217.

56.

von Monakow

. 1911. Lokalisation der Hirnfunktionen [Localization of brain functions]. J Psychol Neurol, 17:185–200.

57.

Wang

, Yu

, Chen

, et al. 2010. Dynamic functional reorganization of the motor execution network after stroke. Brain, 133:1224–1238.

58.

Watson

, Gotts

, Martin

, et al. 2019. Bilateral functional connectivity at rest predicts apraxic symptoms after left hemisphere stroke. Neuroimage Clin, 21:101526.

59.

Wig

. 2017. Segregated systems of human brain networks. Trends Cogn Sci, 21:981–996.

60.

Yang

, Murray

, Wang

, et al. 2016. Functional hierarchy underlies preferential connectivity disturbances in schizophrenia. Proc Natl Acad Sci U S A, 113:E219–E228.

61.

Yeo

, Krienen

, Sepulcre

, et al. 2011. The organization of the human cerebral cortex estimated by intrinsic functional connectivity. J Neurophysiol, 106:1125–1165.

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Reduced Segregation of Brain Networks in Spatial Neglect After Stroke

Abstract

Background/Purpose:

Methods:

Results:

Conclusion:

Impact statement

Get full access to this article

References

Supplementary Material