Your search keyword '"Brain network connectivity"' showing total 34 results

1. Beta oscillation modulations of the orienting attention network effect correlate with dopamine-dependent motor symptoms of Parkinson's disease.

Author

Jiang, Bo, Ding, Lei, Chen, Keke, Huang, Qiwei, Han, Xingyu, Jin, Zhaohui, Cao, Li-Zhi, Zhang, Jianxu, Li, Qing, Xue, Cuiping, He, Yiliu, Fang, Boyan, Pei, Guangying, and Yan, Tianyi

Subjects

*EXECUTIVE function, *CONTROL (Psychology), *COGNITIVE psychology, *DOPAMINE agents, *FUNCTIONAL connectivity

Abstract

Attention impairment, a prevalent non-motor symptom in Parkinson's disease (PD), plays a crucial role in movement disorders. PD patients exhibit abnormalities in the attentional network related to alerting, orienting, and executive control. While dopamine medications have well-documented effects on motor function, their impact on attention networks and the underlying neural mechanisms involved in motor functions remain unclear. In this study, we utilized a modified attention network test to investigate the neural correlates underlying attention network effects measured by electroencephalography (EEG) in 29 PD patients, both on and off dopamine medication and examined their association with motor performance. Interestingly, we found that dopamine medication specifically modulated the orienting effect of the attention network. We analyzed event-related potential components, time-frequency oscillations, and brain network connectivity, as determined by the weighted phase lag index, within the orienting effect under different dopamine medication states. We observed that event-related desynchronization in the betalow, event-related synchronization in the betahigh, and functional connectivity of the betalow in the frontal, central, and parietal were regulated by dopamine medication in the orienting effect. We discovered an association between the attention network's orienting effect and motor performance alterations, which may be attributed to enhanced functional connectivity within the betalow-brain network. Enhanced weighted phase lag index of the betalow-brain network in the orienting effect may contribute to dopamine-dependent changes in motor performance. These preliminary findings provide insights into the EEG mechanisms that underlie the impact of the orienting effect in individuals with PD, shedding light on the influence of dopamine medication and its potential role in regulating top-down attention processes. These findings could help in the advancement of substitution strategies and may have the potential to address both motor and cognitive deficits in PD patients. [ABSTRACT FROM AUTHOR]

Published

2025

2. Social goals in girls transitioning to adolescence: associations with psychopathology and brain network connectivity

Author

Pelletier-Baldelli, Andrea, Sheridan, Margaret A, Glier, Sarah, Rodriguez-Thompson, Anais, Gates, Kathleen M, Martin, Sophia, Dichter, Gabriel S, Patel, Kinjal K, Bonar, Adrienne S, Giletta, Matteo, Hastings, Paul D, Nock, Matthew K, Slavich, George M, Rudolph, Karen D, Prinstein, Mitchell J, and Miller, Adam Bryant

Subjects

Psychology, Applied and Developmental Psychology, Neurosciences, Mental Health, Clinical Research, Brain Disorders, Basic Behavioral and Social Science, Pediatric, Prevention, Behavioral and Social Science, Mind and Body, Pediatric Research Initiative, 2.3 Psychological, social and economic factors, Aetiology, Mental health, Female, Humans, Adolescent, Child, Goals, Psychopathology, Brain, Motivation, Mental Disorders, social motivation, neurodevelopment, girls, transdiagnostic psychopathology, brain network connectivity, Cognitive Sciences, Experimental Psychology, Biological psychology, Clinical and health psychology

Abstract

The motivation to socially connect with peers increases during adolescence in parallel with changes in neurodevelopment. These changes in social motivation create opportunities for experiences that can impact risk for psychopathology, but the specific motivational presentations that confer greater psychopathology risk are not fully understood. To address this issue, we used a latent profile analysis to identify the multidimensional presentations of self-reported social goals in a sample of 220 girls (9-15 years old, M = 11.81, SD = 1.81) that was enriched for internalizing symptoms, and tested the association between social goal profiles and psychopathology. Associations between social goals and brain network connectivity were also examined in a subsample of 138 youth. Preregistered analyses revealed four unique profiles of social goal presentations in these girls. Greater psychopathology was associated with heightened social goals such that higher clinical symptoms were related to a greater desire to attain social competence, avoid negative feedback and gain positive feedback from peers. The profiles endorsing these excessive social goals were characterized by denser connections among social-affective and cognitive control brain regions. These findings thus provide preliminary support for adolescent-onset changes in motivating factors supporting social engagement that may contribute to risk for psychopathology in vulnerable girls.

Published

2023

3. Research on Node Cluster Analysis in Brain Connection Data

Author

Dongye, Guangcheng, Liu, Tao, Bi, Wenhao, Jing, Ming, Zhang, Li, Yu, Jiguo, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Cao, Cungeng, editor, Chen, Huajun, editor, Zhao, Liang, editor, Arshad, Junaid, editor, Asyhari, Taufiq, editor, and Wang, Yonghao, editor

Published

2024

4. Network connectivity underlying information processing speed in children: Application of a pediatric brain tumor survivor injury model

Author

Noor Z. Al Dahhan, Arthur S. Powanwe, Minarose Ismail, Elizabeth Cox, Julie Tseng, Cynthia de Medeiros, Suzanne Laughlin, Eric Bouffet, Jérémie Lefebvre, and Donald J. Mabbott

Subjects

Structure-function coupling, Brain network connectivity, Cognitive performance, Computer applications to medicine. Medical informatics, R858-859.7, Neurology. Diseases of the nervous system, RC346-429

Abstract

Elucidating how adaptive and maladaptive changes to the structural connectivity of brain networks influences neural synchrony, and how this structure–function coupling impacts cognition is an important question in human neuroscience. This study assesses these links in the default mode and executive control networks during resting state, a visual-motor task, and through computational modeling in the developing brain and in acquired brain injuries. Pediatric brain tumor survivors were used as an injury model as they are known to exhibit cognitive deficits, structural connectivity compromise, and perturbations in neural communication. Focusing on information processing speed to assess cognitive performance, we demonstrate that during the presence and absence of specific task demands, structural connectivity of these critical brain networks directly influences neural communication and information processing speed, and white matter compromise has an indirect adverse impact on reaction time via perturbed neural synchrony. Further, when our experimentally acquired structural connectomes simulated neural activity, the resulting functional simulations aligned with our empirical results and accurately predicted cognitive group differences. Overall, our synergistic findings further our understanding of the neural underpinnings of cognition and when it is perturbed. Further establishing alterations in structural–functional coupling as biomarkers of cognitive impairments could facilitate early intervention and monitoring of these deficits.

Published

2024

5. Comparison of Resting-State EEG Network Analyses With and Without Parallel MRI in Genetic Generalized Epilepsy.

Author

van de Velden, Daniel, Stier, Christina, Kotikalapudi, Raviteja, Heide, Ev-Christin, Garnica-Agudelo, David, and Focke, Niels K.

Abstract

Genetic generalized epilepsy (GGE) is conceptualized as a brain disorder involving distributed bilateral networks. To study these networks, simultaneous EEG-fMRI measurements can be used. However, inside-MRI EEG suffers from strong MR-related artifacts; it is not established whether EEG-based metrics in EEG-fMRI resting-state measurements are suitable for the analysis of group differences at source-level. We evaluated the impact of the inside-MR measurement condition on statistical group comparisons of EEG on source-level power and functional connectivity in patients with GGE versus healthy controls. We studied the cross-modal spatial relation of statistical group differences in seed-based FC derived from EEG and parallel fMRI. We found a significant increase in power and a frequency-specific change in functional connectivity for the inside MR-scanner compared to the outside MR-scanner condition. For power, we found reduced group difference between GGE and controls both in terms of statistical significance as well as effect size. Group differences for ImCoh remained similar both in terms of statistical significance as well as effect size. We found increased seed-based FC for GGE patients from the thalamus to the precuneus cortex region in fMRI, and in the theta band of simultaneous EEG. Our findings suggest that the analysis of EEG functional connectivity based on ImCoh is suitable for MR-EEG, and that relative group difference in a comparison of patients with GGE against controls are preserved. Spatial correspondence of seed-based FC group differences between the two modalities was found for the thalamus. [ABSTRACT FROM AUTHOR]

Published

2023

6. Brain Network Connectivity Analysis of Different ADHD Groups Based on CNN-LSTM Classification Model

Author

He, Yuchao, Wang, Cheng, Wang, Xin, Zhu, Mingxing, Chen, Shixiong, Li, Guanglin, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Liu, Honghai, editor, Yin, Zhouping, editor, Liu, Lianqing, editor, Jiang, Li, editor, Gu, Guoying, editor, Wu, Xinyu, editor, and Ren, Weihong, editor

Published

2022

7. Cortical Pathways During Postural Control: New Insights From Functional EEG Source Connectivity

Author

Fabio Barollo, Mahmoud Hassan, Hannes Petersen, Isotta Rigoni, Ceon Ramon, Paolo Gargiulo, and Antonio Fratini

Subjects

Brain network connectivity, EEG, postural control, Medical technology, R855-855.5, Therapeutics. Pharmacology, RM1-950

Abstract

Postural control is a complex feedback system that relies on vast array of sensory inputs in order to maintain a stable upright stance. The brain cortex plays a crucial role in the processing of this information and in the elaboration of a successful adaptive strategy to external stimulation preventing loss of balance and falls. In the present work, the participants postural control system was challenged by disrupting the upright stance via a mechanical skeletal muscle vibration applied to the calves. The EEG source connectivity method was used to investigate the cortical response to the external stimulation and highlight the brain network primarily involved in high-level coordination of the postural control system. The cortical network reconfiguration was assessed during two experimental conditions of eyes open and eyes closed and the network flexibility (i.e. its dynamic reconfiguration over time) was correlated with the sample entropy of the stabilogram sway. The results highlight two different cortical strategies in the alpha band: the predominance of frontal lobe connections during open eyes and the strengthening of temporal-parietal network connections in the absence of visual cues. Furthermore, a high correlation emerges between the flexibility in the regions surrounding the right temporo-parietal junction and the sample entropy of the CoP sway, suggesting their centrality in the postural control system. These results open the possibility to employ network-based flexibility metrics as markers of a healthy postural control system, with implications in the diagnosis and treatment of postural impairing diseases.

Published

2022

8. Cortical Pathways During Postural Control: New Insights From Functional EEG Source Connectivity.

Author

Barollo, Fabio, Hassan, Mahmoud, Petersen, Hannes, Rigoni, Isotta, Ramon, Ceon, Gargiulo, Paolo, and Fratini, Antonio

Subjects

ELECTROENCEPHALOGRAPHY, LARGE-scale brain networks, BRAIN stimulation, FRONTAL lobe, CALVES, SKELETAL muscle

Abstract

Postural control is a complex feedback system that relies on vast array of sensory inputs in order to maintain a stable upright stance. The brain cortex plays a crucial role in the processing of this information and in the elaboration of a successful adaptive strategy to external stimulation preventing loss of balance and falls. In the present work, the participants postural control system was challenged by disrupting the upright stance via a mechanical skeletal muscle vibration applied to the calves. The EEG source connectivity method was used to investigate the cortical response to the external stimulation and highlight the brain network primarily involved in high-level coordination of the postural control system. The cortical network reconfiguration was assessed during two experimental conditions of eyes open and eyes closed and the network flexibility (i.e. its dynamic reconfiguration over time) was correlated with the sample entropy of the stabilogram sway. The results highlight two different cortical strategies in the alpha band: the predominance of frontal lobe connections during open eyes and the strengthening of temporal-parietal network connections in the absence of visual cues. Furthermore, a high correlation emerges between the flexibility in the regions surrounding the right temporo-parietal junction and the sample entropy of the CoP sway, suggesting their centrality in the postural control system. These results open the possibility to employ network-based flexibility metrics as markers of a healthy postural control system, with implications in the diagnosis and treatment of postural impairing diseases. [ABSTRACT FROM AUTHOR]

Published

2022

9. Early motor network connectivity after stroke: An interplay of general reorganization and state‐specific compensation.

Author

Paul, Theresa, Hensel, Lukas, Rehme, Anne K., Tscherpel, Caroline, Eickhoff, Simon B., Fink, Gereon R., Grefkes, Christian, and Volz, Lukas J.

Subjects

*FUNCTIONAL magnetic resonance imaging, *FUNCTIONAL connectivity, *ISCHEMIC stroke

Abstract

Motor recovery after stroke relies on functional reorganization of the motor network, which is commonly assessed via functional magnetic resonance imaging (fMRI)‐based resting‐state functional connectivity (rsFC) or task‐related effective connectivity (trEC). Measures of either connectivity mode have been shown to successfully explain motor impairment post‐stroke, posing the question whether motor impairment is more closely reflected by rsFC or trEC. Moreover, highly similar changes in ipsilesional and interhemispheric motor network connectivity have been reported for both rsFC and trEC after stroke, suggesting that altered rsFC and trEC may capture similar aspects of information integration in the motor network reflecting principle, state‐independent mechanisms of network reorganization rather than state‐specific compensation strategies. To address this question, we conducted the first direct comparison of rsFC and trEC in a sample of early subacute stroke patients (n = 26, included on average 7.3 days post‐stroke). We found that both rsFC and trEC explained motor impairment across patients, stressing the clinical potential of fMRI‐based connectivity. Importantly, intrahemispheric connectivity between ipsilesional M1 and premotor areas depended on the activation state, whereas interhemispheric connectivity between homologs was state‐independent. From a mechanistic perspective, our results may thus arise from two distinct aspects of motor network plasticity: task‐specific compensation within the ipsilesional hemisphere and a more fundamental form of reorganization between hemispheres. [ABSTRACT FROM AUTHOR]

Published

2021

10. Infant social interactions and brain development: A systematic review.

Author

Ilyka, Dianna, Johnson, Mark H., and Lloyd-Fox, Sarah

Subjects

*NEURAL development, *INFANTS, *SOCIAL interaction, *TEENAGERS, *SOCIAL exchange

Abstract

[Display omitted] • Associations between caregiver-infant behaviours during social interactions and brain development outcomes were investigated. • Caregivers' and infants' behaviours in interactions related to children's structural, functional and connectivity measures. • Concurrent associations between behavioural and brain measures were apparent as early as three months postnatally. • Long-term associations between behaviours in early interactions and brain development outcomes were observed decades later. • Individual differences in early interactions and associated brain development is an important avenue for further research. From birth, interactions with others are an integral part of a person's daily life. In infancy, social exchanges are thought to be critical for optimal brain development. This systematic review explores this association by drawing together infant studies that relate adult-infant behaviours – coded from their social interactions - to children's brain measures collected during a neuroimaging session in infancy, childhood, adolescence or adulthood. In total, we identified 55 studies that explored associations between infants' social interactions and neural measures. These studies show that several aspects of caregiver-infant behaviours are associated with, or predict, a variety of neural responses in infants, children and adolescents. The presence of both concurrent and long-term associations - some of which are first observed just a few months postnatally and extend into adulthood - open an important research avenue and motivate further longitudinal studies. [ABSTRACT FROM AUTHOR]

Published

2021

11. Spatiospectral brain networks reflective of improvisational experience

Author

Josef Faller, Andrew Goldman, Yida Lin, James R. McIntosh, and Paul Sajda

Subjects

Musical improvisation, Brain network connectivity, Electroencephalography (EEG), Phase slope index (PSI), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Musical improvisers are trained to categorize certain musical structures into functional classes, which is thought to facilitate improvisation. Using a novel auditory oddball paradigm (Goldman et al., 2020) which enables us to disassociate a deviant (i.e. musical chord inversion) from a consistent functional class, we recorded scalp EEG from a group of musicians who spanned a range of improvisational and classically trained experience. Using a spatiospectral based inter and intra network connectivity analysis, we found that improvisers showed a variety of differences in connectivity within and between large-scale cortical networks compared to classically trained musicians, as a function of deviant type. Inter-network connectivity in the alpha band, for a time window leading up to the behavioural response, was strongly linked to improvisation experience, with the default mode network acting as a hub. Spatiospectral networks post response were substantially different between improvisers and classically trained musicians, with greater inter-network connectivity (specific to the alpha and beta bands) seen in improvisers whereas those with more classical training had largely reduced inter-network activity (mostly in the gamma band). More generally, we interpret our findings in the context of network-level correlates of expectation violation as a function of subject expertise, and we discuss how these may generalize to other and more ecologically valid scenarios.

Published

2021

12. Visuospatial dysfunction is associated with posterior distribution of white matter damage in non‐demented cerebral amyloid angiopathy.

Author

Su, Ya, Fu, Jiayu, Zhang, Yanrong, Xu, Jiajie, Dong, Qiang, and Cheng, Xin

Subjects

*CEREBRAL amyloid angiopathy, *WHITE matter (Nerve tissue), *DIFFUSION tensor imaging, *SPACE perception, *VISUAL perception, *COGNITION

Abstract

Background and purpose: Cerebral amyloid angiopathy (CAA) is a well‐recognized contributor to cognitive decline in the elderly. The posterior cortical predilection of CAA pathology would cause visuospatial dysfunction, which is still underexplored. We aimed to investigate whether the visuospatial dysfunction in CAA is associated with the posterior distribution of small vessel disease (SVD) imaging markers. Methods: We recruited 60 non‐demented CAA cases from a Chinese prospective cohort and 30 cases with non‐CAA SVD as controls. We used the Visual Object and Space Perception (VOSP) battery to evaluate visuospatial abilities, and multivariable regression models to assess their associations with SVD imaging markers. Results: There was visuospatial dysfunction, especially visual object perception impairment, in CAA compared to controls (Z‐score of VOSP: −0.11 ± 0.66 vs. 0.22 ± 0.54, p = 0.023). The VOSP score in CAA was independently related to the fronto‐occipital gradient of white matter hyperintensity volumes (coefficient = 0.03, 95% confidence interval [CI] = 0.003–0.05, p = 0.030) and mean fractional anisotropy values on diffusion tensor imaging (coefficient = 4.72, 95% CI = 0.97–8.48, p = 0.015), but not the severity of global SVD imaging markers or the gradient of lobar cerebral microbleeds with adjustments for age and global cognition score. Conclusions: This finding suggests that the damage of posterior white matter rather than global disease severity may be a major contributor to visuospatial dysfunction in CAA. [ABSTRACT FROM AUTHOR]

Published

2021

13. Prenatal and childhood air pollution exposure, cellular immune biomarkers, and brain connectivity in early adolescents.

Author

Cotter DL, Morrel J, Sukumaran K, Cardenas-Iniguez C, Schwartz J, and Herting MM

Abstract

Introduction: Ambient air pollution is a neurotoxicant with hypothesized immune-related mechanisms. Adolescent brain structural and functional connectivity may be especially vulnerable to ambient pollution due to the refinement of large-scale brain networks during this period, which vary by sex and have important implications for cognitive, behavioral, and emotional functioning. In the current study we explored associations between air pollutants, immune markers, and structural and functional connectivity in early adolescence by leveraging cross-sectional sex-stratified data from the Adolescent Brain Cognitive Development℠ Study®., Methods: Pollutant concentrations of fine particulate matter, nitrogen dioxide, and ozone were assigned to each child's primary residential address during the prenatal period and childhood (9-10 years-old) using an ensemble-based modeling approach. Data collected at 11-13 years-old included resting-state functional connectivity of the default mode, frontoparietal, and salience networks and limbic regions of interest, intracellular directional and isotropic diffusion of available white matter tracts, and markers of cellular immune activation. Using partial least squares correlation, a multivariate data-driven method that identifies important variables within latent dimensions, we investigated associations between 1) pollutants and structural and functional connectivity, 2) pollutants and immune markers, and 3) immune markers and structural and functional connectivity, in each sex separately., Results: Air pollution exposure was related to white matter intracellular directional and isotropic diffusion at ages 11-13 years, but the direction of associations varied by sex. There were no associations between pollutants and resting-state functional connectivity at ages 11-13 years. Childhood exposure to nitrogen dioxide was negatively correlated with white blood cell count in males. Immune biomarkers were positively correlated with white matter intracellular directional diffusion in females and both white matter intracellular directional and isotropic diffusion in males. Lastly, there was a reliable negative correlation between lymphocyte-to-monocyte ratio and default mode network resting-state functional connectivity in females, as well as a compromised immune marker profile associated with lower resting-state functional connectivity between the salience network and the left hippocampus in males. In post-hoc exploratory analyses, we found that the PLSC-identified white matter tracts and resting-state networks related to processing speed and cognitive control performance from the NIH Toolbox., Conclusions: We identified novel links between childhood nitrogen dioxide and cellular immune activation in males, and brain network connectivity and immune markers in both sexes. Future research should explore the potentially mediating role of immune activity in how pollutants affect neurological outcomes as well as the potential consequences of immune-related patterns of brain connectivity in service of improved brain health for all., Competing Interests: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Dr. Megan Herting, PhD reports financial support was provided by 10.13039/100000066National Institute of Environmental Health Sciences. Dr. Joel D. Schwartz, PhD reports financial support was provided by 10.13039/100000139United States Environmental Protection Agency., (© 2024 The Authors.)

Published

2024

14. Functional brain network modeling in sub-acute stroke patients and healthy controls during rest and continuous attentive tracking

Author

Erlend S. Dørum, Tobias Kaufmann, Dag Alnæs, Geneviève Richard, Knut K. Kolskår, Andreas Engvig, Anne-Marthe Sanders, Kristine Ulrichsen, Hege Ihle-Hansen, Jan Egil Nordvik, and Lars T. Westlye

Subjects

Cerebral stroke, fMRI, Brain network connectivity, Machine learning, Behavioral neuroscience, Cognitive neuroscience, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

A cerebral stroke is characterized by compromised brain function due to an interruption in cerebrovascular blood supply. Although stroke incurs focal damage determined by the vascular territory affected, clinical symptoms commonly involve multiple functions and cognitive faculties that are insufficiently explained by the focal damage alone. Functional connectivity (FC) refers to the synchronous activity between spatially remote brain regions organized in a network of interconnected brain regions. Functional magnetic resonance imaging (fMRI) has advanced this system-level understanding of brain function, elucidating the complexity of stroke outcomes, as well as providing information useful for prognostic and rehabilitation purposes.We tested for differences in brain network connectivity between a group of patients with minor ischemic strokes in sub-acute phase (n = 44) and matched controls (n = 100). As neural network configuration is dependent on cognitive effort, we obtained fMRI data during rest and two load levels of a multiple object tracking (MOT) task. Network nodes and time-series were estimated using independent component analysis (ICA) and dual regression, with network edges defined as the partial temporal correlations between node pairs. The full set of edgewise FC went into a cross-validated regularized linear discriminant analysis (rLDA) to classify groups and cognitive load.MOT task performance and cognitive tests revealed no significant group differences. While multivariate machine learning revealed high sensitivity to experimental condition, with classification accuracies between rest and attentive tracking approaching 100%, group classification was at chance level, with negligible differences between conditions. Repeated measures ANOVA showed significantly stronger synchronization between a temporal node and a sensorimotor node in patients across conditions. Overall, the results revealed high sensitivity of FC indices to task conditions, and suggest relatively small brain network-level disturbances after clinically mild strokes.

Published

2020

15. Biomarkers of seizure response to vagus nerve stimulation: A scoping review.

Author

Workewych, Adriana M., Arski, Olivia N., Mithani, Karim, and Ibrahim, George M.

Subjects

*NEURAL stimulation, *VAGUS nerve, *SEIZURES (Medicine), *HEART beat, *BIOMARKERS

Abstract

Although vagus nerve stimulation (VNS) is a common procedure, seizure outcomes are heterogeneous, with few available means to preoperatively identify the ideal surgical candidate. Here, we perform a scoping review of the literature to identify biomarkers of VNS response in patients with drug‐resistant epilepsy. Several databases (Ovid MEDLINE, Ovid Embase, BIOSIS Previews, and Web of Science) were searched for all relevant articles that reported at least one biomarker of VNS response following implantation for intractable epilepsy. Patient demographics, seizure data, and details related to biomarkers were abstracted from all studies. From the 288 records screened, 28 articles reporting on 16 putative biomarkers were identified. These were grouped into four categories: network/connectomic‐based biomarkers, electrophysiological signatures, structural findings on neuroimaging, and systemic assays. Differences in brain network organization, connectivity, and electrophysiological synchronicity demonstrated the most robust ability to identify VNS responders. Structural findings on neuroimaging yielded inconsistent associations with VNS responsiveness. With regard to systemic biomarkers, heart rate variability was shown to be an independent marker of VNS response, whereas inflammatory markers were not useful. There is an unmet need to preoperatively identify candidates who are likely to benefit from VNS. Several biomarkers demonstrate promise in predicting seizure responsiveness to VNS, particularly measures of brain network connectivity. Further efforts are required to validate existing biomarkers to inform clinical decision‐making. [ABSTRACT FROM AUTHOR]

Published

2020

16. Prenatal developmental origins of behavior and mental health: The influence of maternal stress in pregnancy.

Author

Van den Bergh, Bea R.H., van den Heuvel, Marion I., Lahti, Marius, Braeken, Marijke, de Rooij, Susanne R., Entringer, Sonja, Hoyer, Dirk, Roseboom, Tessa, Räikkönen, Katri, King, Suzanne, and Schwab, Matthias

Subjects

*HEALTH behavior, *MENTAL health, *BIOLOGICAL systems, *PSYCHOLOGICAL distress, *MENTAL illness

Abstract

• Maternal psychological distress, life event stress, and objective exposure affect offspring outcome. • Functional and structural brain changes underlie the problems observed in the offspring. • Alterations in stress system, immune system, and gut microbiome play a significant role. • Epigenetic and telomere biology mechanisms are beginning to be explored. • Interventions focused on offspring also need to be guided by knowledge of changes in biological systems. Accumulating research shows that prenatal exposure to maternal stress increases the risk for behavioral and mental health problems later in life. This review systematically analyzes the available human studies to identify harmful stressors, vulnerable periods during pregnancy, specificities in the outcome and biological correlates of the relation between maternal stress and offspring outcome. Effects of maternal stress on offspring neurodevelopment, cognitive development, negative affectivity, difficult temperament and psychiatric disorders are shown in numerous epidemiological and case-control studies. Offspring of both sexes are susceptible to prenatal stress but effects differ. There is not any specific vulnerable period of gestation; prenatal stress effects vary for different gestational ages possibly depending on the developmental stage of specific brain areas and circuits, stress system and immune system. Biological correlates in the prenatally stressed offspring are: aberrations in neurodevelopment, neurocognitive function, cerebral processing, functional and structural brain connectivity involving amygdalae and (pre)frontal cortex, changes in hypothalamo-pituitary-adrenal (HPA)-axis and autonomous nervous system. [ABSTRACT FROM AUTHOR]

Published

2020

17. Ordinal Patterns for Connectivity Networks in Brain Disease Diagnosis

Author

Liu, Mingxia, Du, Junqiang, Jie, Biao, Zhang, Daoqiang, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Ourselin, Sebastien, editor, Joskowicz, Leo, editor, Sabuncu, Mert R., editor, Unal, Gozde, editor, and Wells, William, editor

Published

2016

18. The Neural Architecture of General Knowledge.

Author

Genç, Erhan, Fraenz, Christoph, Schlüter, Caroline, Friedrich, Patrick, Voelkle, Manuel C., Hossiep, Rüdiger, Güntürkün, Onur, and Mõttus, René

Subjects

*FLUID intelligence, *DIFFUSION tensor imaging, *FUNCTIONAL magnetic resonance imaging, *CRYSTALLIZED intelligence

Abstract

Cognitive performance varies widely between individuals and is highly influenced by structural and functional properties of the brain. In the past, neuroscientific research was principally concerned with fluid intelligence, while neglecting its equally important counterpart crystallized intelligence. Crystallized intelligence is defined as the depth and breadth of knowledge and skills that are valued by one's culture. The accumulation of crystallized intelligence is guided by information storage capacities and is likely to be reflected in an individual's level of general knowledge. In spite of the significant role general knowledge plays for everyday life, its neural foundation largely remains unknown. In a large sample of 324 healthy individuals, we used standard magnetic resonance imaging along with functional magnetic resonance imaging and diffusion tensor imaging to examine different estimates of brain volume and brain network connectivity and assessed their predictive power with regard to both general knowledge and fluid intelligence. Our results demonstrate that an individual's level of general knowledge is associated with structural brain network connectivity beyond any confounding effects exerted by age or sex. Moreover, we found fluid intelligence to be best predicted by cortex volume in male subjects and functional network connectivity in female subjects. Combined, these findings potentially indicate different neural architectures for information storage and information processing. © 2019 European Association of Personality Psychology [ABSTRACT FROM AUTHOR]

Published

2019

19. Corrigendum: Static and Dynamic Measures of Human Brain Connectivity Predict Complementary Aspects of Human Cognitive Performance

Author

Aurora I. Ramos-Nuñez, Simon Fischer-Baum, Randi C. Martin, Qiuhai Yue, Fengdan Ye, and Michael W. Deem

Subjects

flexibility, modularity, resting-state fMRI, task complexity, individual differences, brain network connectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2018

20. Static and Dynamic Measures of Human Brain Connectivity Predict Complementary Aspects of Human Cognitive Performance

Author

Aurora I. Ramos-Nuñez, Simon Fischer-Baum, Randi C. Martin, Qiuhai Yue, Fengdan Ye, and Michael W. Deem

Subjects

flexibility, modularity, resting-state fMRI, task complexity, individual differences, brain network connectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

In cognitive network neuroscience, the connectivity and community structure of the brain network is related to measures of cognitive performance, like attention and memory. Research in this emerging discipline has largely focused on two measures of connectivity—modularity and flexibility—which, for the most part, have been examined in isolation. The current project investigates the relationship between these two measures of connectivity and how they make separable contribution to predicting individual differences in performance on cognitive tasks. Using resting state fMRI data from 52 young adults, we show that flexibility and modularity are highly negatively correlated. We use a Brodmann parcellation of the fMRI data and a sliding window approach for calculation of the flexibility. We also demonstrate that flexibility and modularity make unique contributions to explain task performance, with a clear result showing that modularity, not flexibility, predicts performance for simple tasks and that flexibility plays a greater role in predicting performance on complex tasks that require cognitive control and executive functioning. The theory and results presented here allow for stronger links between measures of brain network connectivity and cognitive processes.

Published

2017

21. Brain network connectivity in women exposed to intimate partner violence: a graph theory analysis study.

Author

Roos, Annerine, Fouche, Jean-Paul, Stein, Dan, and Stein, Dan J

Subjects

ANTHROPOMETRY, BRAIN, DIGITAL image processing, MAGNETIC resonance imaging, NEURAL pathways

Abstract

Evidence suggests that women who suffer from intimate partner violence (IPV) and posttraumatic stress disorder (PTSD) have structural and functional alterations in specific brain regions. Yet, little is known about how brain connectivity may be altered in individuals with IPV, but without PTSD. Women exposed to IPV (n = 18) and healthy controls (n = 18) underwent structural brain imaging using a Siemens 3T MRI. Global and regional brain network connectivity measures were determined, using graph theory analyses. Structural covariance networks were created using volumetric and cortical thickness data after controlling for intracranial volume, age and alcohol use. Nonparametric permutation tests were used to investigate group differences. Findings revealed altered connectivity on a global and regional level in the IPV group of regions involved in cognitive-emotional control, with principal involvement of the caudal anterior cingulate, the middle temporal gyrus, left amygdala and ventral diencephalon that includes the thalamus. To our knowledge, this is the first evidence showing different brain network connectivity in global and regional networks in women exposed to IPV, and without PTSD. Altered cognitive-emotional control in IPV may underlie adaptive neural mechanisms in environments characterized by potentially dangerous cues. [ABSTRACT FROM AUTHOR]

Published

2017

22. Static and Dynamic Measures of Human Brain Connectivity Predict Complementary Aspects of Human Cognitive Performance.

Author

Ramos-Nuñez, Aurora I., Fischer-Baum, Simon, Martin, Randi C., Qiuhai Yue, Fengdan Ye, and Deem, Michael W.

Subjects

BRAIN, COGNITIVE ability, NEUROSCIENCES, INDIVIDUAL differences, BIOLOGICAL neural networks

Abstract

In cognitive network neuroscience, the connectivity and community structure of the brain network is related to measures of cognitive performance, like attention and memory. Research in this emerging discipline has largely focused on two measures of connectivity--modularity and flexibility--which, for the most part, have been examined in isolation. The current project investigates the relationship between these two measures of connectivity and how they make separable contribution to predicting individual differences in performance on cognitive tasks. Using resting state fMRI data from 52 young adults, we show that flexibility and modularity are highly negatively correlated. We use a Brodmann parcellation of the fMRI data and a sliding window approach for calculation of the flexibility. We also demonstrate that flexibility and modularity make unique contributions to explain task performance, with a clear result showing that modularity, not flexibility, predicts performance for simple tasks and that flexibility plays a greater role in predicting performance on complex tasks that require cognitive control and executive functioning. The theory and results presented here allow for stronger links between measures of brain network connectivity and cognitive processes. [ABSTRACT FROM AUTHOR]

Published

2017

23. Increased sensitivity to age-related differences in brain functional connectivity during continuous multiple object tracking compared to resting-state.

Author

Dørum, Erlend S., Kaufmann, Tobias, Alnæs, Dag, Andreassen, Ole A., Richard, Geneviève, Kolskår, Knut K., Nordvik, Jan Egil, and Westlye, Lars T.

Subjects

*BRAIN physiology, *AGE differences, *OBJECT tracking (Computer vision), *MOTOR ability, *FUNCTIONAL magnetic resonance imaging

Abstract

Age-related differences in cognitive agility vary greatly between individuals and cognitive functions. This heterogeneity is partly mirrored in individual differences in brain network connectivity as revealed using resting-state functional magnetic resonance imaging (fMRI), suggesting potential imaging biomarkers for age-related cognitive decline. However, although convenient in its simplicity, the resting state is essentially an unconstrained paradigm with minimal experimental control. Here, based on the conception that the magnitude and characteristics of age-related differences in brain connectivity is dependent on cognitive context and effort, we tested the hypothesis that experimentally increasing cognitive load boosts the sensitivity to age and changes the discriminative network configurations. To this end, we obtained fMRI data from younger (n=25, mean age 24.16±5.11) and older (n=22, mean age 65.09±7.53) healthy adults during rest and two load levels of continuous multiple object tracking (MOT). Brain network nodes and their time-series were estimated using independent component analysis (ICA) and dual regression, and the edges in the brain networks were defined as the regularized partial temporal correlations between each of the node pairs at the individual level. Using machine learning based on a cross-validated regularized linear discriminant analysis (rLDA) we attempted to classify groups and cognitive load from the full set of edge-wise functional connectivity indices. While group classification using resting-state data was highly above chance (approx. 70% accuracy), functional connectivity (FC) obtained during MOT strongly increased classification performance, with 82% accuracy for the young and 95% accuracy for the old group at the highest load level. Further, machine learning revealed stronger differentiation between rest and task in young compared to older individuals, supporting the notion of network dedifferentiation in cognitive aging. Task-modulation in edgewise FC was primarily observed between attention- and sensorimotor networks; with decreased negative correlations between attention- and default mode networks in older adults. These results demonstrate that the magnitude and configuration of age-related differences in brain functional connectivity are partly dependent on cognitive context and load, which emphasizes the importance of assessing brain connectivity differences across a range of cognitive contexts beyond the resting-state. [ABSTRACT FROM AUTHOR]

Published

2017

24. A brain-region-based meta-analysis method utilizing the Apriori algorithm.

Author

Zhendong Niu, Yaoxin Nie, Qian Zhou, Linlin Zhu, Jieyao Wei, Niu, Zhendong, Nie, Yaoxin, Zhou, Qian, Zhu, Linlin, and Wei, Jieyao

Subjects

*META-analysis, *APRIORI algorithm, *BRAIN imaging, *FUNCTIONAL magnetic resonance imaging, *BRAIN function localization, *BRAIN physiology, *ALGORITHMS, *BAR codes, *BIOLOGICAL models, *BRAIN, *LITERATURE, *MAGNETIC resonance imaging, *MAPS, *NEUROLOGIC examination, *READING, *POSITRON emission tomography, *DATA mining, *NEURAL pathways, *PHYSIOLOGY

Abstract

Background: Brain network connectivity modeling is a crucial method for studying the brain's cognitive functions. Meta-analyses can unearth reliable results from individual studies. Meta-analytic connectivity modeling is a connectivity analysis method based on regions of interest (ROIs) which showed that meta-analyses could be used to discover brain network connectivity.Results: In this paper, we propose a new meta-analysis method that can be used to find network connectivity models based on the Apriori algorithm, which has the potential to derive brain network connectivity models from activation information in the literature, without requiring ROIs. This method first extracts activation information from experimental studies that use cognitive tasks of the same category, and then maps the activation information to corresponding brain areas by using the automatic anatomical label atlas, after which the activation rate of these brain areas is calculated. Finally, using these brain areas, a potential brain network connectivity model is calculated based on the Apriori algorithm. The present study used this method to conduct a mining analysis on the citations in a language review article by Price (Neuroimage 62(2):816-847, 2012). The results showed that the obtained network connectivity model was consistent with that reported by Price.Conclusions: The proposed method is helpful to find brain network connectivity by mining the co-activation relationships among brain regions. Furthermore, results of the co-activation relationship analysis can be used as a priori knowledge for the corresponding dynamic causal modeling analysis, possibly achieving a significant dimension-reducing effect, thus increasing the efficiency of the dynamic causal modeling analysis. [ABSTRACT FROM AUTHOR]

Published

2016

25. Prenatal developmental origins of behavior and mental health

Subjects

Gut microbiome, Depression, Autism, Attention deficit hyperactivity disorder (ADHD), Event related potential (ERP), Anxiety, Brain network connectivity, Cortisol, Functional magnetic resonance imaging (fMRI), Life events, HPA-axis, Maternal psychological distress, Objective stress, Fetal programming, Pregnancy-specific anxiety, Schizophrenia, Autonomic nervous system, Epigenetics, Disaster exposure, EEG, Psychiatric disorders, Heart rate variability, Telomere biology

Abstract

Accumulating research shows that prenatal exposure to maternal stress increases the risk for behavioral and mental health problems later in life. This review systematically analyzes the available human studies to identify harmful stressors, vulnerable periods during pregnancy, specificities in the outcome and biological correlates of the relation between maternal stress and offspring outcome. Effects of maternal stress on offspring neurodevelopment, cognitive development, negative affectivity, difficult temperament and psychiatric disorders are shown in numerous epidemiological and case-control studies. Offspring of both sexes are susceptible to prenatal stress but effects differ. There is not any specific vulnerable period of gestation; prenatal stress effects vary for different gestational ages possibly depending on the developmental stage of specific brain areas and circuits, stress system and immune system. Biological correlates in the prenatally stressed offspring are: aberrations in neurodevelopment, neurocognitive function, cerebral processing, functional and structural brain connectivity involving amygdalae and (pre)frontal cortex, changes in hypothalamo-pituitary-adrenal (HPA)-axis and autonomous nervous system.

Published

2020

26. Frequency of Hospitalizations for Pain and Association With Altered Brain Network Connectivity in Sickle Cell Disease.

Author

Darbari, Deepika S., Hampson, Johnson P., Ichesco, Eric, Kadom, Nadja, Vezina, Gilbert, Evangelou, Iordanis, Clauw, Daniel J., Taylor VI, James G., and Harris, Richard E.

Abstract

Unlabelled: Sickle cell disease (SCD) is a hemoglobinopathy that affects more than 100,000 individuals in the United States. The disease is characterized by the presence of sickle hemoglobin and recurrent episodes of pain. Some individuals with SCD experience frequent hospitalizations and a high burden of pain. The role of central mechanisms in SCD pain has not been explored. Twenty-five adolescents and young adults with SCD underwent functional magnetic resonance imaging. Participants were stratified into groups with high pain or low pain based on the number of hospitalizations for pain in the preceding 12 months. Resting state functional connectivity was analyzed using seed-based and dual regression independent component analysis. Intrinsic brain connectivity was compared between the high pain and low pain groups, and association with fetal hemoglobin, a known modifier of SCD, was explored. Patients in the high pain group displayed an excess of pronociceptive connectivity such as between anterior cingulate and default mode network structures, such as the precuneus, whereas patients in the low pain group showed more connectivity to antinociceptive structures such as the perigenual and subgenual cingulate. Although a similar proportion of patients in both groups reported that they were on hydroxyurea, the fetal hemoglobin levels were significantly higher in the low pain group and were associated with greater connectivity to antinociceptive structures. These findings support the role of central mechanisms in SCD pain. Intrinsic brain connectivity should be explored as a complementary and objective outcome measure in SCD pain research.Perspective: Altered connectivity patterns associated with high pain experience in patients with sickle cell disease suggest a possible role of central mechanisms in sickle cell pain. Resting state brain connectivity studies should be explored as an effective methodology to investigate pain in SCD. [ABSTRACT FROM AUTHOR]

Published

2015

27. Attentional load modulates large-scale functional brain connectivity beyond the core attention networks.

Author

Alnæs, Dag, Kaufmann, Tobias, Richard, Geneviève, Duff, Eugene P., Sneve, Markus H., Endestad, Tor, Nordvik, Jan Egil, Andreassen, Ole A., Smith, Stephen M., and Westlye, Lars T.

Subjects

*BRAIN physiology, *NEURAL circuitry, *BIOLOGICAL crosstalk, *FUNCTIONAL magnetic resonance imaging, *MEMBRANE potential, *COGNITIVE ability

Abstract

In line with the notion of a continuously active and dynamic brain, functional networks identified during rest correspond with those revealed by task-fMRI. Characterizing the dynamic cross-talk between these network nodes is key to understanding the successful implementation of effortful cognitive processing in healthy individuals and its breakdown in a variety of conditions involving aberrant brain biology and cognitive dysfunction. We employed advanced network modeling on fMRI data collected during a task involving sustained attentive tracking of objects at two load levels and during rest. Using multivariate techniques, we demonstrate that attentional load levels can be significantly discriminated, and from a resting-state condition, the accuracy approaches 100%, by means of estimates of between-node functional connectivity. Several network edges were modulated during task engagement: The dorsal attention network increased connectivity with a visual node, while decreasing connectivity with motor and sensory nodes. Also, we observed a decoupling between left and right hemisphere dorsal visual streams. These results support the notion of dynamic network reconfigurations based on attentional effort. No simple correspondence between node signal amplitude change and node connectivity modulations was found, thus network modeling provides novel information beyond what is revealed by conventional task-fMRI analysis. The current decoding of attentional states confirms that edge connectivity contains highly predictive information about the mental state of the individual, and the approach shows promise for the utilization in clinical contexts. [ABSTRACT FROM AUTHOR]

Published

2015

28. Comparison of statistical tests for group differences in brain functional networks.

Author

Kim, Junghi, Wozniak, Jeffrey R., Mueller, Bryon A., Shen, Xiaotong, and Pan, Wei

Subjects

*BRAIN function localization, *TIME series analysis, *BRAIN imaging, *STATISTICAL power analysis, *MAGNETIC resonance imaging of the brain, *EUCLIDEAN distance

Abstract

Brain functional connectivity has been studied by analyzing time series correlations in regional brain activities based on resting-state fMRI data. Brain functional connectivity can be depicted as a network or graph defined as a set of nodes linked by edges. Nodes represent brain regions and an edge measures the strength of functional correlation between two regions. Most of existing work focuses on estimation of such a network. A key but inadequately addressed question is how to test for possible differences of the networks between two subject groups, say between healthy controls and patients. Here we illustrate and compare the performance of several state-of-the-art statistical tests drawn from the neuroimaging, genetics, ecology and high-dimensional data literatures. Both real and simulated data were used to evaluate the methods. We found that Network Based Statistic (NBS) performed well in many but not all situations, and its performance critically depends on the choice of its threshold parameter, which is unknown and difficult to choose in practice. Importantly, two adaptive statistical tests called adaptive sum of powered score (aSPU) and its weighted version (aSPUw) are easy to use and complementary to NBS, being higher powered than NBS in some situations. The aSPU and aSPUw tests can also be applied to adjust for covariates. Between the aSPU and aSPUw tests, they often, but not always, performed similarly with neither one as a uniform winner. On the other hand, Multivariate Matrix Distance Regression (MDMR) has been applied to detect group differences for brain connectivity; with the usual choice of the Euclidean distance, MDMR is a special case of the aSPU test. Consequently NBS, aSPU and aSPUw tests are recommended to test for group differences in functional connectivity. [ABSTRACT FROM AUTHOR]

Published

2014

29. Prenatal developmental origins of behavior and mental health: The influence of maternal stress in pregnancy

Author

Van den Bergh, Bea R H, van den Heuvel, Marion I, Lahti, Marius, Braeken, Marijke, de Rooij, Susanne R, Entringer, Sonja, Hoyer, Dirk, Roseboom, Tessa, Räikkönen, Katri, King, Suzanne, Schwab, Matthias, Van den Bergh, Bea R H, van den Heuvel, Marion I, Lahti, Marius, Braeken, Marijke, de Rooij, Susanne R, Entringer, Sonja, Hoyer, Dirk, Roseboom, Tessa, Räikkönen, Katri, King, Suzanne, and Schwab, Matthias

Abstract

Accumulating research shows that prenatal exposure to maternal stress increases the risk for behavioral and mental health problems later in life. This review systematically analyzes the available human studies to identify harmful stressors, vulnerable periods during pregnancy, specificities in the outcome and biological correlates of the relation between maternal stress and offspring outcome. Effects of maternal stress on offspring neurodevelopment, cognitive development, negative affectivity, difficult temperament and psychiatric disorders are shown in numerous epidemiological and case-control studies. Offspring of both sexes are susceptible to prenatal stress but effects differ. There is not any specific vulnerable period of gestation; prenatal stress effects vary for different gestational ages possibly depending on the developmental stage of specific brain areas and circuits, stress system and immune system. Biological correlates in the prenatally stressed offspring are: aberrations in neurodevelopment, neurocognitive function, cerebral processing, functional and structural brain connectivity involving amygdalae and (pre)frontal cortex, changes in hypothalamo-pituitary-adrenal (HPA)-axis and autonomous nervous system.

Published

2020

30. Functional brain network modeling in sub-acute stroke patients and healthy controls during rest and continuous attentive tracking

Author

Jan Egil Nordvik, Tobias Kaufmann, Kristine Moe Ulrichsen, Dag Alnæs, Andreas Engvig, Lars T. Westlye, Erlend S. Dørum, Geneviève Richard, Anne-Marthe Sanders, Hege Ihle-Hansen, and Knut K. Kolskår

Subjects

0301 basic medicine, medicine.medical_specialty, Neurology, medicine.medical_treatment, Cognitive neuroscience, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Machine learning, medicine, lcsh:Social sciences (General), lcsh:Science (General), Stroke, Multidisciplinary, Rehabilitation, medicine.diagnostic_test, Behavioral neuroscience, business.industry, fMRI, Systems neuroscience, Cerebral stroke, Repeated measures design, Cognition, Brain network connectivity, Linear discriminant analysis, medicine.disease, Cognitive test, 030104 developmental biology, lcsh:H1-99, Medical imaging, Functional magnetic resonance imaging, business, 030217 neurology & neurosurgery, Cognitive load, lcsh:Q1-390, Research Article

Abstract

A cerebral stroke is characterized by compromised brain function due to an interruption in cerebrovascular blood supply. Although stroke incurs focal damage determined by the vascular territory affected, clinical symptoms commonly involve multiple functions and cognitive faculties that are insufficiently explained by the focal damage alone. Functional connectivity (FC) refers to the synchronous activity between spatially remote brain regions organized in a network of interconnected brain regions. Functional magnetic resonance imaging (fMRI) has advanced this system-level understanding of brain function, elucidating the complexity of stroke outcomes, as well as providing information useful for prognostic and rehabilitation purposes. We tested for differences in brain network connectivity between a group of patients with minor ischemic strokes in sub-acute phase (n = 44) and matched controls (n = 100). As neural network configuration is dependent on cognitive effort, we obtained fMRI data during rest and two load levels of a multiple object tracking (MOT) task. Network nodes and time-series were estimated using independent component analysis (ICA) and dual regression, with network edges defined as the partial temporal correlations between node pairs. The full set of edgewise FC went into a cross-validated regularized linear discriminant analysis (rLDA) to classify groups and cognitive load. MOT task performance and cognitive tests revealed no significant group differences. While multivariate machine learning revealed high sensitivity to experimental condition, with classification accuracies between rest and attentive tracking approaching 100%, group classification was at chance level, with negligible differences between conditions. Repeated measures ANOVA showed significantly stronger synchronization between a temporal node and a sensorimotor node in patients across conditions. Overall, the results revealed high sensitivity of FC indices to task conditions, and suggest relatively small brain network-level disturbances after clinically mild strokes., Cerebral stroke, fMRI, Brain network connectivity, Machine learning, Behavioral Neuroscience, Cognitive Neuroscience, Systems Neuroscience, Neurology, Medical Imaging

Published

2019

31. Brain network connectivity in women exposed to intimate partner violence: a graph theory analysis study

Author

Roos, Annerine, Fouche, Jean-Paul, and Stein, Dan J.

Published

2016

32. Corrigendum: Static and Dynamic Measures of Human Brain Connectivity Predict Complementary Aspects of Human Cognitive Performance.

Author

Ramos-Nuñez, Aurora I., Fischer-Baum, Simon, Martin, Randi C., Yue, Qiuhai, Ye, Fengdan, and Deem, Michael W.

Subjects

BRAIN, COGNITIVE ability

Abstract

A correction to the article "Static and Dynamic Measures of Human Brain Connectivity Predict Complementary Aspects of Human Cognitive Performance" that was published in 2017 issue of the periodical, is presented.

Published

2018

33. Understanding Neuroplastic Effects of Transcranial Direct Current Stimulation through Analysis of Dynamics of Large-Scale Brain Networks

Author

Venkatakrishnan, Anusha and Venkatakrishnan, Anusha

Abstract

Intrinsic adult neuroplasticity plays a critical role in learning and memory as well as mediating functional recovery from brain lesions like stroke and traumatic brain injuries. Extrinsic strategies to aid favorable modulation of neuroplasticity act as important adjunctive tools of neurorehabilitation. Transcranial direct current stimulation (tDCS) is an example of a non-invasive technique that can successfully induce neuroplastic changes in the human brain, although the underlying mechanisms are not completely understood. In this regard, characterization of neuroplastic changes in large-scale brain networks is a functional and necessary step towards non-invasively understanding neuroplastic modulation mediated by tDCS in humans. This dissertation, thus, aimed to understand the effects of tDCS, on large-scale brain network dynamics recorded through magnetoencephalography (MEG) through three specific aims that will provide novel insights into the mechanism(s) through which plastic changes are promoted by tDCS, specifically in the context motor learning. This dissertation pursued a systematic investigation of these changes in whole-head cortical dynamics using both model-free and model-based analysis techniques. Two experiments were conducted to dissociate between network changes mediated by tDCS at rest as well as when coupled with a task in order to determine optimal conditions for using tDCS for clinical purposes. Results from Study 1 using model-free analysis showed that a specific fronto-parietal network at rest was modulated up to a period of 30 minutes outlasting the duration of the stimulation. Further model-based analysis of this fronto-parietal network showed that these differences were driven by network activity primarily involving high frequency gamma band connectivity to and from the supplementary motor area to associated regions (left primary motor cortex (stimulated region), left prefrontal and parietal cortices). Results from Study 2 showed that the t

Published

2012

34. [Research development of real-time functional magnetic resonance imaging neuro-feedback technology based on brain network connectivity].

Author

He W, Bu H, Tong L, Liu F, Zeng Y, Wang L, and Yan B

Abstract

The emergence of real-time functional magnetic resonance imaging (rt-fMRI) has provided foundations for neurofeedback based on brain hemodynamics and has given the new opportunity and challenge to cognitive neuroscience research. Along with the study of advanced brain neural mechanisms, the regulation goal of rt-fMRI neurofeedback develops from the early specific brain region activity to the brain network connectivity more accordant with the brain functional activities, and the study of the latter may be a trend in the area. Firstly, this paper introduces basic principle and development of rt-fMRI neurofeedback. Then, it specifically discusses the current research status of brain connectivity neurofeedback technology, including research approaches, experimental methods, conclusions, and so on. Finally, it discusses the problems in this field in the future development.

Published

2017