Local inhibitory plasticity tunes macroscopic brain dynamics and allows the emergence of functional brain networks

Hellyer, Peter J.; Jachs, Barbara; Clopath, Claudia; Leech, Robert

doi:10.1016/j.neuroimage.2015.08.069

Cited by 92 publications

(173 citation statements)

References 63 publications

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“…The relationship between brain dynamics and cognitive function is complex and likely depends on both brain state and cognitive domain. With respect to state, our findings are in line with a previous study showing low levels of dFC, but high levels of sFC, during task engagement, whereas at rest the brain displayed an opposite pattern (Hellyer et al., ). Furthermore, it could be hypothesized that certain cognitive domains benefit more from high levels of dFC than others.…”

Section: Discussionsupporting

confidence: 92%

“…Recent studies indicate that the dynamics of FC (dFC) are indeed related to cognitive function in healthy subjects and certain patient populations (Cole et al, 2013;Douw, Wakeman, Tanaka, Liu, & Stufflebeam, 2016;Douw et al, 2015;Hellyer, Jachs, Clopath, & Leech, 2016;Nguyen et al, 2016), and that dFC may supersede traditional neuroimaging measures in explaining cognitive variance (Douw et al, 2015(Douw et al, , 2016Jia, Hu, & Deshpande, 2014;Nguyen et al, 2016). This body of literature is heterogeneous, but suggests that the relationship between dFC and cognition depends on the combination of the brain state in which it is measured (at rest or during a task) and the cognitive domain investigated.…”

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confidence: 99%

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The importance of hippocampal dynamic connectivity in explaining memory function in multiple sclerosis

et al. 2018

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IntroductionBrain dynamics (i.e., variable strength of communication between areas), even at the scale of seconds, are thought to underlie complex human behavior, such as learning and memory. In multiple sclerosis (MS), memory problems occur often and have so far only been related to “stationary” brain measures (e.g., atrophy, lesions, activation and stationary (s) functional connectivity (FC) over an entire functional scanning session). However, dynamics in FC (dFC) between the hippocampus and the (neo)cortex may be another important neurobiological substrate of memory impairment in MS that has not yet been explored. Therefore, we investigated hippocampal dFC during a functional (f) magnetic resonance imaging (MRI) episodic memory task and its relationship with verbal and visuospatial memory performance outside the MR scanner.MethodsThirty‐eight MS patients and 29 healthy controls underwent neuropsychological tests to assess memory function. Imaging (1.5T) was obtained during performance of a memory task. We assessed hippocampal volume, functional activation, and sFC (i.e., FC of the hippocampus with the rest of the brain averaged over the entire scan, using an atlas‐based approach). Dynamic FC of the hippocampus was calculated using a sliding window approach.ResultsNo group differences were found in hippocampal activation, sFC, and dFC. However, stepwise forward regression analyses in patients revealed that lower dFC of the left hippocampus (standardized β = −0.30; p = .021) could explain an additional 7% of variance (53% in total) in verbal memory, in addition to female sex and larger left hippocampal volume. For visuospatial memory, lower dFC of the right hippocampus (standardized β = −0.38; p = .013) could explain an additional 13% of variance (24% in total) in addition to higher sFC of the right hippocampus.ConclusionLow hippocampal dFC is an important indicator for maintained memory performance in MS, in addition to other hippocampal imaging measures. Hence, brain dynamics may offer new insights into the neurobiological mechanisms underlying memory (dys)function.

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Section: Discussionsupporting

confidence: 92%

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confidence: 99%

The importance of hippocampal dynamic connectivity in explaining memory function in multiple sclerosis

et al. 2018

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“…This is consistent with a homeostatic neuroplasticity model of intelligence in which maintenance of an optimal small-world dynamic involves minimizing long distance information processing and maximizing the efficiency of local information processing29. Phase reset operates primarily in the local hub domain to recruit and allocate resources to efficiently process information while information flow operates in the long range compartments to compensate for inefficiencies in the local domain.…”

Section: Discussionsupporting

confidence: 78%

Intelligence and eeg measures of information flow: efficiency and homeostatic neuroplasticity

Thatcher¹,

Palmero‐Soler²,

North³

et al. 2016

Sci Rep

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The purpose of this study was to explore the relationship between the magnitude of EEG information flow and intelligence. The electroencephalogram (EEG) was recorded from 19 scalp locations from 371 subjects ranging in age from 5 years to 17.6 years. The Wechler Intelligence Scale for Children (WISC-R) was administered for individuals between 5 years of age and 16 years and the Weschler Adult Intelligence Scale revised (WAIS-R) was administered to subjects older than 16 years to estimate I.Q. The phase slope index estimated the magnitude of information flow between all electrode combinations for difference frequency bands. Discriminant analyses were performed between high I.Q. (>120) and low I.Q. groups (<90). The magnitude of information flow was inversely related to I.Q. especially in the alpha and beta frequency bands. Long distance inter-electrode distances exhibited greater information flow than short inter-electrode distances. Frontal-parietal correlations were the most significant. It is concluded that higher I.Q. is related to increased efficiency of local information processing and reduced long distance compensatory dynamics that supports a small-world model of intelligence.

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“…A strong link between cognitive flexibility and creative performance has been demonstrated in previous studies736. Recent studies have indicated that cognitive flexibility is highly associated with neural metastability162737. A greater dFC state transition frequency enables the brain regions of creative individuals to engage and disengage more flexibly without experiencing locked interactions.…”

Section: Discussionmentioning

confidence: 72%

High transition frequencies of dynamic functional connectivity states in the creative brain

Zhang

Liang³

et al. 2017

Sci Rep

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Creativity is thought to require the flexible reconfiguration of multiple brain regions that interact in transient and complex communication patterns. In contrast to prior emphases on searching for specific regions or networks associated with creative performance, we focused on exploring the association between the reconfiguration of dynamic functional connectivity states and creative ability. We hypothesized that a high frequency of dynamic functional connectivity state transitions will be associated with creative ability. To test this hypothesis, we recruited a high-creative group (HCG) and a low-creative group (LCG) of participants and collected resting-state fMRI (R-fMRI) data and Torrance Tests of Creative Thinking (TTCT) scores from each participant. By combining an independent component analysis with a dynamic network analysis approach, we discovered the HCG had more frequent transitions between dynamic functional connectivity (dFC) states than the LCG. Moreover, a confirmatory analysis using multiplication of temporal derivatives also indicated that there were more frequent dFC state transitions in the HCG. Taken together, these results provided empirical evidence for a linkage between the flexible reconfiguration of dynamic functional connectivity states and creative ability. These findings have the potential to provide new insights into the neural basis of creativity.

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Local inhibitory plasticity tunes macroscopic brain dynamics and allows the emergence of functional brain networks

Cited by 92 publications

References 63 publications

The importance of hippocampal dynamic connectivity in explaining memory function in multiple sclerosis

The importance of hippocampal dynamic connectivity in explaining memory function in multiple sclerosis

Intelligence and eeg measures of information flow: efficiency and homeostatic neuroplasticity

High transition frequencies of dynamic functional connectivity states in the creative brain

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