Dynamic reconfiguration of frontal brain networks during executive cognition in humans

Braun, Urs; Schäfer, Axel; Walter, Henrik; Erk, Susanne; Romanczuk-Seiferth, Nina; Haddad, Leila; Schweiger, Janina I.; Grimm, O.; Heinz, Andreas; Tost, Heike; Meyer‐Lindenberg, Andreas; Bassett, Danielle S.

doi:10.1073/pnas.1422487112

Cited by 690 publications

(809 citation statements)

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“…Crucially, connector nodes are also not involved in all betweenmodule connectivity. Nonconnector node regions play a role as well (28,87,93,94), and, as noted above, increased betweenmodule connectivity that is not routed through connector nodes has been found during many different tasks, and differentiates task connectivity from resting-state connectivity (36). Although the current and previous findings suggest that connector node regions coordinate some of these between-module connections, it is likely that other mechanisms for between-module communication exist that are executed by nonconnector nodes.…”

Section: Discussionmentioning

(Expert classified)

“…Although the current and previous findings suggest that connector node regions coordinate some of these between-module connections, it is likely that other mechanisms for between-module communication exist that are executed by nonconnector nodes. In line with this, connector nodes are not the only nodes that change module membership during tasks (87,93). For example, an fMRI study of a 2-back task showed that, although many connector node regions changed module membership and this predicted higher performance, the regions with the most module membership changes were in ventromedial prefrontal cortex, where no connector nodes were located in our analysis (93).…”

Section: Discussionmentioning

confidence: 54%

“…In line with this, connector nodes are not the only nodes that change module membership during tasks (87,93). For example, an fMRI study of a 2-back task showed that, although many connector node regions changed module membership and this predicted higher performance, the regions with the most module membership changes were in ventromedial prefrontal cortex, where no connector nodes were located in our analysis (93). Finally, although connector node regions all exhibit the graph theoretic property of a high participation coefficient, these regions do not all have identical cytoarchitecture and their connectivity profiles are to different modules.…”

Section: Discussionmentioning

confidence: 92%

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The modular and integrative functional architecture of the human brain

Bertolero

Yeo

D’Esposito

2015

Proc. Natl. Acad. Sci. U.S.A.

490

478

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Network-based analyses of brain imaging data consistently reveal distinct modules and connector nodes with diverse global connectivity across the modules. How discrete the functions of modules are, how dependent the computational load of each module is to the other modules' processing, and what the precise role of connector nodes is for between-module communication remains underspecified. Here, we use a network model of the brain derived from resting-state functional MRI (rs-fMRI) data and investigate the modular functional architecture of the human brain by analyzing activity at different types of nodes in the network across 9,208 experiments of 77 cognitive tasks in the BrainMap database. Using an authortopic model of cognitive functions, we find a strong spatial correspondence between the cognitive functions and the network's modules, suggesting that each module performs a discrete cognitive function. Crucially, activity at local nodes within the modules does not increase in tasks that require more cognitive functions, demonstrating the autonomy of modules' functions. However, connector nodes do exhibit increased activity when more cognitive functions are engaged in a task. Moreover, connector nodes are located where brain activity is associated with many different cognitive functions. Connector nodes potentially play a role in betweenmodule communication that maintains the modular function of the brain. Together, these findings provide a network account of the brain's modular yet integrated implementation of cognitive functions. modularity | hubs | cognition | graph theory | network

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Section: Discussionmentioning

(Expert classified)

Section: Discussionmentioning

confidence: 54%

Section: Discussionmentioning

confidence: 92%

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The modular and integrative functional architecture of the human brain

Bertolero

Yeo

D’Esposito

2015

Proc. Natl. Acad. Sci. U.S.A.

490

478

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“…The architecture of the human brain is intrinsically organized into time-varying assemblies of functionally interacting nodes (16,18), a dynamic neural community structure allowing for high adaptability of the system to changing environmental demands (29). Schizophrenia is increasingly recognized as a heritable brain disorder with altered neural network dynamics, yet the presence of alterations in the time-varying configuration of the functional connectome and their genetic and pharmacological implications require clarification.…”

Section: Discussionmentioning

confidence: 99%

“…Unlike the "static" network approaches, these methods allow for the quantification of contextdependent changes of the network community structure over time (e.g., during learning or cognitive load), which is arguably a biologically more accurate description of normal and disordered brain network dynamics (16,18,19). Moreover, the temporal variability of the neural community structure predicts learning (16) and executive function (18) in normal volunteers, which are two established deficit areas in schizophrenia (20,21). The temporal dynamic thus appears to reflect the capacity of the brain connectome to configure flexibly in support of cognitive demands, a feature that may relate to the genetic risk architecture of schizophrenia.…”

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confidence: 99%

Dynamic brain network reconfiguration as a potential schizophrenia genetic risk mechanism modulated by NMDA receptor function

Braun

Schäfer

Bassett

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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185

184

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Schizophrenia is increasingly recognized as a disorder of distributed neural dynamics, but the molecular and genetic contributions are poorly understood. Recent work highlights a role for altered N-methyl-D-aspartate (NMDA) receptor signaling and related impairments in the excitation-inhibitory balance and synchrony of large-scale neural networks. Here, we combined a pharmacological intervention with novel techniques from dynamic network neuroscience applied to functional magnetic resonance imaging (fMRI) to identify alterations in the dynamic reconfiguration of brain networks related to schizophrenia genetic risk and NMDA receptor hypofunction. We quantified "network flexibility," a measure of the dynamic reconfiguration of the community structure of time-variant brain networks during working memory performance. Comparing 28 patients with schizophrenia, 37 unaffected first-degree relatives, and 139 healthy controls, we detected significant differences in network flexibility [F(2,196) = 6.541, P = 0.002] in a pattern consistent with the assumed genetic risk load of the groups (highest for patients, intermediate for relatives, and lowest for controls). In an observer-blinded, placebo-controlled, randomized, cross-over pharmacological challenge study in 37 healthy controls, we further detected a significant increase in network flexibility as a result of NMDA receptor antagonism with 120 mg dextromethorphan [F(1,34) = 5.291, P = 0.028]. Our results identify a potential dynamic network intermediate phenotype related to the genetic liability for schizophrenia that manifests as altered reconfiguration of brain networks during working memory. The phenotype appears to be influenced by NMDA receptor antagonism, consistent with a critical role for glutamate in the temporal coordination of neural networks and the pathophysiology of schizophrenia. S chizophrenia is a highly heritable mental disorder for which aberrant interactions between brain regions or "dysconnectivity" have been proposed as a core neural mechanism (1). Functional magnetic resonance imaging (fMRI) studies demonstrate alterations in specific neural subcircuits in schizophrenia (2, 3) that are under genetic control (4), although recent data from network neuroscience point to more widespread disturbances in the dynamics of large-scale brain networks (5, 6). Uhlhaas (5), Uhlhaas and Singer (6), and Phillips and Silverstein (7) have proposed a plausible pathophysiological mechanism for these phenomena: They argue that alterations in the cellular excitation-inhibitory balance may lead to disturbances in the neural synchrony of large-scale cell ensembles and give rise to the dysconnectivity phenomena at the level of neural ensembles.The neural excitation-inhibitory balance is highly dependent on glutamatergic N-methyl-D-aspartate (NMDA) receptor function (8), and alterations in NMDA receptor signaling have been associated with schizophrenia risk (9), disorder-related cognitive abnormalities (10, 11), and deficits in the temporal coordination of large-scale bra...

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Transdiagnostic Associations Between Functional Brain Network Integrity and Cognition

et al. 2017

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IMPORTANCE Cognitive impairment occurs across the psychosis spectrum and is associated with functional outcome. However, it is unknown whether these shared manifestations of cognitive dysfunction across diagnostic categories also reflect shared neurobiological mechanisms or whether the source of impairment differs. OBJECTIVE To examine whether the general cognitive deficit observed across psychotic disorders is similarly associated with functional integrity of 2 brain networks widely implicated in supporting many cognitive domains. DESIGN, SETTING, AND PARTICIPANTS A total of 201 healthy control participants and 375 patients with psychotic disorders from the Bipolar-Schizophrenia Network on Intermediate Phenotypes (B-SNIP) consortium were studied from September 29, 2007, to May 31, 2011. The B-SNIP recruited healthy controls and stable outpatients from 6 sites: Baltimore, Maryland; Boston, Massachusetts; Chicago, Illinois; Dallas, Texas; Detroit, Michigan; and Hartford, Connecticut. All participants underwent cognitive testing and resting-state functional magnetic resonance imaging. Data analysis was performed from April 28, 2015, to February 21, 2017. MAIN OUTCOMES AND MEASURES The Brief Assessment of Cognition in Schizophrenia was used to measure cognitive ability. A principal axis factor analysis on the Brief Assessment of Cognition in Schizophrenia battery yielded a single factor (54% variance explained) that served as the measure of general cognitive ability. Functional network integrity measures included global and local efficiency of the whole brain, cingulo-opercular network (CON), frontoparietal network, and auditory network and exploratory analyses of all networks from the Power atlas. Group differences in network measures, associations between cognition and network measures, and mediation models were tested. RESULTS The final sample for the current study included 201 healthy controls, 143 patients with schizophrenia, 103 patients with schizoaffective disorder, and 129 patients with psychotic bipolar disorder (mean [SD] age, 35.1 [12.0] years; 281 male [48.8%] and 295 female [51.2%]; 181 white [31.4%], 348 black [60.4%], and 47 other [8.2%]). Patients with schizophrenia (Cohen d = 0.36, P < .001) and psychotic bipolar disorder (Cohen d = 0.33, P = .002) had significantly reduced CON global efficiency compared with healthy controls. All patients with psychotic disorders had significantly reduced CON local efficiency, but the clinical groups did not differ from one another. The CON global efficiency was significantly associated with general cognitive ability across all groups (β = 0.099, P = .009) and significantly mediated the association between psychotic disorder status and general cognition (β = −0.037; 95% CI, −0.076 to −0.014). Subcortical network global efficiency was also significantly reduced in psychotic disorders (F3,587 = 4.01, P = .008) and positively predicted cognitive ability (β = 0.094, P = .009). CONCLUSIONS AND RELEVANCE These findings provide evidence that reduced CON and s...

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Dynamic reconfiguration of frontal brain networks during executive cognition in humans

Cited by 690 publications

References 62 publications

The modular and integrative functional architecture of the human brain

The modular and integrative functional architecture of the human brain

Dynamic brain network reconfiguration as a potential schizophrenia genetic risk mechanism modulated by NMDA receptor function

Transdiagnostic Associations Between Functional Brain Network Integrity and Cognition

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