Your search keyword '"McIntosh AR"' showing total 29 results

1. Inferring multi-scale neural mechanisms with brain network modelling.

Author

Schirner M, McIntosh AR, Jirsa V, Deco G, and Ritter P

Subjects

Adult, Aged, Computer Simulation, Electroencephalography, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Young Adult, Brain anatomy & histology, Brain physiology, Models, Neurological, Nerve Net anatomy & histology, Nerve Net physiology

Abstract

The neurophysiological processes underlying non-invasive brain activity measurements are incompletely understood. Here, we developed a connectome-based brain network model that integrates individual structural and functional data with neural population dynamics to support multi-scale neurophysiological inference. Simulated populations were linked by structural connectivity and, as a novelty, driven by electroencephalography (EEG) source activity. Simulations not only predicted subjects' individual resting-state functional magnetic resonance imaging (fMRI) time series and spatial network topologies over 20 minutes of activity, but more importantly, they also revealed precise neurophysiological mechanisms that underlie and link six empirical observations from different scales and modalities: (1) resting-state fMRI oscillations, (2) functional connectivity networks, (3) excitation-inhibition balance, (4, 5) inverse relationships between α-rhythms, spike-firing and fMRI on short and long time scales, and (6) fMRI power-law scaling. These findings underscore the potential of this new modelling framework for general inference and integration of neurophysiological knowledge to complement empirical studies., Competing Interests: MS, AM, VJ, GD, PR No competing interests declared, (© 2018, Schirner et al.)

Published

2018

2. Mapping complementary features of cross-species structural connectivity to construct realistic "Virtual Brains".

Author

Bezgin G, Solodkin A, Bakker R, Ritter P, and McIntosh AR

Subjects

Adolescent, Adult, Algorithms, Animals, Brain diagnostic imaging, Connectome, Databases, Factual, Diffusion Tensor Imaging, Female, Humans, Image Processing, Computer-Assisted, Macaca, Male, Models, Statistical, Neural Pathways diagnostic imaging, Neural Pathways physiology, Species Specificity, Young Adult, Brain anatomy & histology, Brain Mapping, Libraries, Digital, Models, Neurological, Neural Pathways anatomy & histology

Abstract

Modern systems neuroscience increasingly leans on large-scale multi-lab neuroinformatics initiatives to provide necessary capacity for biologically realistic modeling of primate whole-brain activity. Here, we present a framework to assemble primate brain's biologically plausible anatomical backbone for such modeling initiatives. In this framework, structural connectivity is determined by adding complementary information from invasive macaque axonal tract tracing and non-invasive human diffusion tensor imaging. Both modalities are combined by means of available interspecies registration tools and a newly developed Bayesian probabilistic modeling approach to extract common connectivity evidence. We demonstrate how this novel framework is embedded in the whole-brain simulation platform called The Virtual Brain (TVB). Hum Brain Mapp 38:2080-2093, 2017. © 2017 Wiley Periodicals, Inc., (© 2017 Wiley Periodicals, Inc.)

Published

2017

3. Multiregional integration in the brain during resting-state fMRI activity.

Author

Hay E, Ritter P, Lobaugh NJ, and McIntosh AR

Subjects

Comorbidity, Models, Statistical, Brain Mapping methods, Cerebral Cortex physiology, Magnetic Resonance Imaging methods, Models, Neurological, Nerve Net physiology, Rest physiology

Abstract

Data-driven models of functional magnetic resonance imaging (fMRI) activity can elucidate dependencies that involve the combination of multiple brain regions. Activity in some regions during resting-state fMRI can be predicted with high accuracy from the activities of other regions. However, it remains unclear in which regions activity depends on unique integration of multiple predictor regions. To address this question, sparse (parsimonious) models could serve to better determine key interregional dependencies by reducing false positives. We used resting-state fMRI data from 46 subjects, and for each region of interest (ROI) per subject we performed whole-brain recursive feature elimination (RFE) to select the minimal set of ROIs that best predicted activity in the modeled ROI. We quantified the dependence of activity on multiple predictor ROIs, by measuring the gain in prediction accuracy of models that incorporated multiple predictor ROIs compared to models that used a single predictor ROI. We identified regions that showed considerable evidence of multiregional integration and determined the key regions that contributed to their observed activity. Our models reveal fronto-parietal integration networks, little integration in primary sensory regions, as well as redundancy between some regions. Our study demonstrates the utility of whole-brain RFE to generate data-driven models with minimal sets of ROIs that predict activity with high accuracy. By determining the extent to which activity in each ROI depended on integration of signals from multiple ROIs, we find cortical integration networks during resting-state activity.

Published

2017

4. Selective Activation of Resting-State Networks following Focal Stimulation in a Connectome-Based Network Model of the Human Brain.

Author

Spiegler A, Hansen EC, Bernard C, McIntosh AR, and Jirsa VK

Subjects

Humans, Neural Pathways physiology, Rest, Time Factors, Brain physiology, Connectome, Electric Stimulation Therapy, Models, Neurological, Transcranial Magnetic Stimulation

Abstract

When the brain is stimulated, for example, by sensory inputs or goal-oriented tasks, the brain initially responds with activities in specific areas. The subsequent pattern formation of functional networks is constrained by the structural connectivity (SC) of the brain. The extent to which information is processed over short- or long-range SC is unclear. Whole-brain models based on long-range axonal connections, for example, can partly describe measured functional connectivity dynamics at rest. Here, we study the effect of SC on the network response to stimulation. We use a human whole-brain network model comprising long- and short-range connections. We systematically activate each cortical or thalamic area, and investigate the network response as a function of its short- and long-range SC. We show that when the brain is operating at the edge of criticality, stimulation causes a cascade of network recruitments, collapsing onto a smaller space that is partly constrained by SC. We found both short- and long-range SC essential to reproduce experimental results. In particular, the stimulation of specific areas results in the activation of one or more resting-state networks. We suggest that the stimulus-induced brain activity, which may indicate information and cognitive processing, follows specific routes imposed by structural networks explaining the emergence of functional networks. We provide a lookup table linking stimulation targets and functional network activations, which potentially can be useful in diagnostics and treatments with brain stimulation.

Published

2016

5. Functional Mechanisms of Recovery after Chronic Stroke: Modeling with the Virtual Brain.

Author

Falcon MI, Riley JD, Jirsa V, McIntosh AR, Chen EE, and Solodkin A

Subjects

Adult, Aged, Brain diagnostic imaging, Case-Control Studies, Chronic Disease, Diffusion Tensor Imaging, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Middle Aged, Psychomotor Performance physiology, Stochastic Processes, Stroke diagnostic imaging, Stroke physiopathology, Young Adult, Brain physiology, Connectome, Models, Neurological, Recovery of Function physiology, Stroke pathology

Abstract

We have seen important strides in our understanding of mechanisms underlying stroke recovery, yet effective translational links between basic and applied sciences, as well as from big data to individualized therapies, are needed to truly develop a cure for stroke. We present such an approach using The Virtual Brain (TVB), a neuroinformatics platform that uses empirical neuroimaging data to create dynamic models of an individual's human brain; specifically, we simulate fMRI signals by modeling parameters associated with brain dynamics after stroke. In 20 individuals with stroke and 11 controls, we obtained rest fMRI, T1w, and diffusion tensor imaging (DTI) data. Motor performance was assessed pre-therapy, post-therapy, and 6-12 months post-therapy. Based on individual structural connectomes derived from DTI, the following steps were performed in the TVB platform: (1) optimization of local and global parameters (conduction velocity, global coupling); (2) simulation of BOLD signal using optimized parameter values; (3) validation of simulated time series by comparing frequency, amplitude, and phase of the simulated signal with empirical time series; and (4) multivariate linear regression of model parameters with clinical phenotype. Compared with controls, individuals with stroke demonstrated a consistent reduction in conduction velocity, increased local dynamics, and reduced local inhibitory coupling. A negative relationship between local excitation and motor recovery, and a positive correlation between local dynamics and motor recovery were seen. TVB reveals a disrupted post-stroke system favoring excitation-over-inhibition and local-over-global dynamics, consistent with existing mammal literature on stroke mechanisms. Our results point to the potential of TVB to determine individualized biomarkers of stroke recovery.

Published

2016

6. An automated pipeline for constructing personalized virtual brains from multimodal neuroimaging data.

Author

Schirner M, Rothmeier S, Jirsa VK, McIntosh AR, and Ritter P

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Female, Humans, Male, Middle Aged, Multimodal Imaging, Young Adult, Brain anatomy & histology, Brain physiology, Connectome methods, Electroencephalography methods, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods, Models, Neurological

Abstract

Large amounts of multimodal neuroimaging data are acquired every year worldwide. In order to extract high-dimensional information for computational neuroscience applications standardized data fusion and efficient reduction into integrative data structures are required. Such self-consistent multimodal data sets can be used for computational brain modeling to constrain models with individual measurable features of the brain, such as done with The Virtual Brain (TVB). TVB is a simulation platform that uses empirical structural and functional data to build full brain models of individual humans. For convenient model construction, we developed a processing pipeline for structural, functional and diffusion-weighted magnetic resonance imaging (MRI) and optionally electroencephalography (EEG) data. The pipeline combines several state-of-the-art neuroinformatics tools to generate subject-specific cortical and subcortical parcellations, surface-tessellations, structural and functional connectomes, lead field matrices, electrical source activity estimates and region-wise aggregated blood oxygen level dependent (BOLD) functional MRI (fMRI) time-series. The output files of the pipeline can be directly uploaded to TVB to create and simulate individualized large-scale network models that incorporate intra- and intercortical interaction on the basis of cortical surface triangulations and white matter tractograpy. We detail the pitfalls of the individual processing streams and discuss ways of validation. With the pipeline we also introduce novel ways of estimating the transmission strengths of fiber tracts in whole-brain structural connectivity (SC) networks and compare the outcomes of different tractography or parcellation approaches. We tested the functionality of the pipeline on 50 multimodal data sets. In order to quantify the robustness of the connectome extraction part of the pipeline we computed several metrics that quantify its rescan reliability and compared them to other tractography approaches. Together with the pipeline we present several principles to guide future efforts to standardize brain model construction. The code of the pipeline and the fully processed data sets are made available to the public via The Virtual Brain website (thevirtualbrain.org) and via github (https://github.com/BrainModes/TVB-empirical-data-pipeline). Furthermore, the pipeline can be directly used with High Performance Computing (HPC) resources on the Neuroscience Gateway Portal (http://www.nsgportal.org) through a convenient web-interface., (Copyright © 2015 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2015

7. Computational modeling of resting-state activity demonstrates markers of normalcy in children with prenatal or perinatal stroke.

Author

Adhikari MH, Raja Beharelle A, Griffa A, Hagmann P, Solodkin A, McIntosh AR, Small SL, and Deco G

Subjects

Brain blood supply, Brain Mapping, Case-Control Studies, Child, Female, Functional Laterality physiology, Humans, Image Processing, Computer-Assisted, Language Disorders etiology, Magnetic Resonance Imaging, Male, Nonlinear Dynamics, Oxygen blood, Brain Injuries etiology, Brain Injuries pathology, Computer Simulation, Models, Neurological, Neural Pathways pathology, Stroke complications

Abstract

Children who sustain a prenatal or perinatal brain injury in the form of a stroke develop remarkably normal cognitive functions in certain areas, with a particular strength in language skills. A dominant explanation for this is that brain regions from the contralesional hemisphere "take over" their functions, whereas the damaged areas and other ipsilesional regions play much less of a role. However, it is difficult to tease apart whether changes in neural activity after early brain injury are due to damage caused by the lesion or by processes related to postinjury reorganization. We sought to differentiate between these two causes by investigating the functional connectivity (FC) of brain areas during the resting state in human children with early brain injury using a computational model. We simulated a large-scale network consisting of realistic models of local brain areas coupled through anatomical connectivity information of healthy and injured participants. We then compared the resulting simulated FC values of healthy and injured participants with the empirical ones. We found that the empirical connectivity values, especially of the damaged areas, correlated better with simulated values of a healthy brain than those of an injured brain. This result indicates that the structural damage caused by an early brain injury is unlikely to have an adverse and sustained impact on the functional connections, albeit during the resting state, of damaged areas. Therefore, these areas could continue to play a role in the development of near-normal function in certain domains such as language in these children., (Copyright © 2015 the authors 0270-6474/15/358914-11$15.00/0.)

Published

2015

8. Network structure shapes spontaneous functional connectivity dynamics.

Author

Shen K, Hutchison RM, Bezgin G, Everling S, and McIntosh AR

Subjects

Animals, Brain blood supply, Female, Image Processing, Computer-Assisted, Macaca fascicularis, Magnetic Resonance Imaging, Male, Neural Pathways blood supply, Oxygen blood, Brain physiology, Brain Mapping, Models, Neurological, Neural Pathways physiology, Nonlinear Dynamics

Abstract

The structural organization of the brain constrains the range of interactions between different regions and shapes ongoing information processing. Therefore, it is expected that large-scale dynamic functional connectivity (FC) patterns, a surrogate measure of coordination between brain regions, will be closely tied to the fiber pathways that form the underlying structural network. Here, we empirically examined the influence of network structure on FC dynamics by comparing resting-state FC (rsFC) obtained using BOLD-fMRI in macaques (Macaca fascicularis) to structural connectivity derived from macaque axonal tract tracing studies. Consistent with predictions from simulation studies, the correspondence between rsFC and structural connectivity increased as the sample duration increased. Regions with reciprocal structural connections showed the most stable rsFC across time. The data suggest that the transient nature of FC is in part dependent on direct underlying structural connections, but also that dynamic coordination can occur via polysynaptic pathways. Temporal stability was found to be dependent on structural topology, with functional connections within the rich-club core exhibiting the greatest stability over time. We discuss these findings in light of highly variable functional hubs. The results further elucidate how large-scale dynamic functional coordination exists within a fixed structural architecture., (Copyright © 2015 the authors 0270-6474/15/355579-10$15.00/0.)

Published

2015

9. A network convergence zone in the hippocampus.

Author

Mišić B, Goñi J, Betzel RF, Sporns O, and McIntosh AR

Subjects

Animals, Computational Biology, Databases, Factual, Macaca, Connectome, Hippocampus physiology, Models, Neurological, Neural Pathways physiology

Abstract

The hippocampal formation is a key structure for memory function in the brain. The functional anatomy of the brain suggests that the hippocampus may be a convergence zone, as it receives polysensory input from distributed association areas throughout the neocortex. However, recent quantitative graph-theoretic analyses of the static large-scale connectome have failed to demonstrate the centrality of the hippocampus; in the context of the whole brain, the hippocampus is not among the most connected or reachable nodes. Here we show that when communication dynamics are taken into account, the hippocampus is a key hub in the connectome. Using a novel computational model, we demonstrate that large-scale brain network topology is organized to funnel and concentrate information flow in the hippocampus, supporting the long-standing hypothesis that this region acts as a critical convergence zone. Our results indicate that the functional capacity of the hippocampus is shaped by its embedding in the large-scale connectome.

Published

2014

10. Using the virtual brain to reveal the role of oscillations and plasticity in shaping brain's dynamical landscape.

Author

Roy D, Sigala R, Breakspear M, McIntosh AR, Jirsa VK, Deco G, and Ritter P

Subjects

Action Potentials physiology, Computer Simulation, Humans, Neural Networks, Computer, Rest, Software, Alpha Rhythm physiology, Cerebral Cortex physiology, Models, Neurological, Nerve Net physiology, Neuronal Plasticity physiology, Neurons physiology

Abstract

Spontaneous brain activity, that is, activity in the absence of controlled stimulus input or an explicit active task, is topologically organized in multiple functional networks (FNs) maintaining a high degree of coherence. These "resting state networks" are constrained by the underlying anatomical connectivity between brain areas. They are also influenced by the history of task-related activation. The precise rules that link plastic changes and ongoing dynamics of resting-state functional connectivity (rs-FC) remain unclear. Using the framework of the open source neuroinformatics platform "The Virtual Brain," we identify potential computational mechanisms that alter the dynamical landscape, leading to reconfigurations of FNs. Using a spiking neuron model, we first demonstrate that network activity in the absence of plasticity is characterized by irregular oscillations between low-amplitude asynchronous states and high-amplitude synchronous states. We then demonstrate the capability of spike-timing-dependent plasticity (STDP) combined with intrinsic alpha (8-12 Hz) oscillations to efficiently influence learning. Further, we show how alpha-state-dependent STDP alters the local area dynamics from an irregular to a highly periodic alpha-like state. This is an important finding, as the cortical input from the thalamus is at the rate of alpha. We demonstrate how resulting rhythmic cortical output in this frequency range acts as a neuronal tuner and, hence, leads to synchronization or de-synchronization between brain areas. Finally, we demonstrate that locally restricted structural connectivity changes influence local as well as global dynamics and lead to altered rs-FC.

Published

2014

11. Identification of optimal structural connectivity using functional connectivity and neural modeling.

Author

Deco G, McIntosh AR, Shen K, Hutchison RM, Menon RS, Everling S, Hagmann P, and Jirsa VK

Subjects

Algorithms, Animals, Humans, Macaca, Nonlinear Dynamics, Brain anatomy & histology, Models, Neurological, Nerve Net physiology, Neural Pathways physiology, Neurons physiology

Abstract

The complex network dynamics that arise from the interaction of the brain's structural and functional architectures give rise to mental function. Theoretical models demonstrate that the structure-function relation is maximal when the global network dynamics operate at a critical point of state transition. In the present work, we used a dynamic mean-field neural model to fit empirical structural connectivity (SC) and functional connectivity (FC) data acquired in humans and macaques and developed a new iterative-fitting algorithm to optimize the SC matrix based on the FC matrix. A dramatic improvement of the fitting of the matrices was obtained with the addition of a small number of anatomical links, particularly cross-hemispheric connections, and reweighting of existing connections. We suggest that the notion of a critical working point, where the structure-function interplay is maximal, may provide a new way to link behavior and cognition, and a new perspective to understand recovery of function in clinical conditions., (Copyright © 2014 the authors 0270-6474/14/347910-07$15.00/0.)

Published

2014

12. Bottom up modeling of the connectome: linking structure and function in the resting brain and their changes in aging.

Author

Nakagawa TT, Jirsa VK, Spiegler A, McIntosh AR, and Deco G

Subjects

Aging physiology, Brain physiology, Humans, Nerve Net physiology, Rest, Aging pathology, Brain anatomy & histology, Connectome methods, Diffusion Tensor Imaging methods, Models, Anatomic, Models, Neurological, Nerve Net anatomy & histology

Abstract

With the increasing availability of advanced imaging technologies, we are entering a new era of neuroscience. Detailed descriptions of the complex brain network enable us to map out a structural connectome, characterize it with graph theoretical methods, and compare it to the functional networks with increasing detail. To link these two aspects and understand how dynamics and structure interact to form functional brain networks in task and in the resting state, we use theoretical models. The advantage of using theoretical models is that by recreating functional connectivity and time series explicitly from structure and pre-defined dynamics, we can extract critical mechanisms by linking structure and function in ways not directly accessible in the real brain. Recently, resting-state models with varying local dynamics have reproduced empirical functional connectivity patterns, and given support to the view that the brain works at a critical point at the edge of a bifurcation of the system. Here, we present an overview of a modeling approach of the resting brain network and give an application of a neural mass model in the study of complexity changes in aging., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

13. Confounding effects of phase delays on causality estimation.

Author

Vakorin VA, Mišić B, Krakovska O, Bezgin G, and McIntosh AR

Subjects

Animals, Causality, Haplorhini, Neurophysiology, Nonlinear Dynamics, Brain physiology, Models, Neurological

Abstract

Linear and non-linear techniques for inferring causal relations between the brain signals representing the underlying neuronal systems have become a powerful tool to extract the connectivity patterns in the brain. Typically these tools employ the idea of Granger causality, which is ultimately based on the temporal precedence between the signals. At the same time, phase synchronization between coupled neural ensembles is considered a mechanism implemented in the brain to integrate relevant neuronal ensembles to perform a cognitive or perceptual task. Phase synchronization can be studied by analyzing the effects of phase-locking between the brain signals. However, we should expect that there is no one-to-one mapping between the observed phase lag and the time precedence as specified by physically interacting systems. Specifically, phase lag observed between two signals may interfere with inferring causal relations. This could be of critical importance for the coupled non-linear oscillating systems, with possible time delays in coupling, when classical linear cross-spectrum strategies for solving phase ambiguity are not efficient. To demonstrate this, we used a prototypical model of coupled non-linear systems, and compared three typical pipelines of inferring Granger causality, as established in the literature. Specifically, we compared the performance of the spectral and information-theoretic Granger pipelines as well as standard Granger causality in their relations to the observed phase differences for frequencies at which the signals become synchronized to each other. We found that an information-theoretic approach, which takes into account different time lags between the past of one signal and the future of another signal, was the most robust to phase effects.

Published

2013

14. The virtual brain integrates computational modeling and multimodal neuroimaging.

Author

Ritter P, Schirner M, McIntosh AR, and Jirsa VK

Subjects

Brain blood supply, Electroencephalography, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Nonlinear Dynamics, Stochastic Processes, Time Factors, Brain physiology, Computer Simulation, Models, Neurological, User-Computer Interface

Abstract

Brain function is thought to emerge from the interactions among neuronal populations. Apart from traditional efforts to reproduce brain dynamics from the micro- to macroscopic scales, complementary approaches develop phenomenological models of lower complexity. Such macroscopic models typically generate only a few selected-ideally functionally relevant-aspects of the brain dynamics. Importantly, they often allow an understanding of the underlying mechanisms beyond computational reproduction. Adding detail to these models will widen their ability to reproduce a broader range of dynamic features of the brain. For instance, such models allow for the exploration of consequences of focal and distributed pathological changes in the system, enabling us to identify and develop approaches to counteract those unfavorable processes. Toward this end, The Virtual Brain (TVB) ( www.thevirtualbrain.org ), a neuroinformatics platform with a brain simulator that incorporates a range of neuronal models and dynamics at its core, has been developed. This integrated framework allows the model-based simulation, analysis, and inference of neurophysiological mechanisms over several brain scales that underlie the generation of macroscopic neuroimaging signals. In this article, we describe how TVB works, and we present the first proof of concept.

Published

2013

15. Hundreds of brain maps in one atlas: registering coordinate-independent primate neuro-anatomical data to a standard brain.

Author

Bezgin G, Vakorin VA, van Opstal AJ, McIntosh AR, and Bakker R

Subjects

Animals, Computer Simulation, Image Interpretation, Computer-Assisted methods, Reference Values, Software, Brain anatomy & histology, Databases, Factual standards, Macaca anatomy & histology, Models, Anatomic, Models, Neurological, Nerve Net anatomy & histology, Subtraction Technique

Abstract

Non-invasive measuring methods such as EEG/MEG, fMRI and DTI are increasingly utilised to extract quantitative information on functional and anatomical connectivity in the human brain. These methods typically register their data in Euclidean space, so that one can refer to a particular activity pattern by specifying its spatial coordinates. Since each of these methods has limited resolution in either the time or spatial domain, incorporating additional data, such as those obtained from invasive animal studies, would be highly beneficial to link structure and function. Here we describe an approach to spatially register all cortical brain regions from the macaque structural connectivity database CoCoMac, which contains the combined tracing study results from 459 publications (http://cocomac.g-node.org). Brain regions from 9 different brain maps were directly mapped to a standard macaque cortex using the tool Caret (Van Essen and Dierker, 2007). The remaining regions in the CoCoMac database were semantically linked to these 9 maps using previously developed algebraic and machine-learning techniques (Bezgin et al., 2008; Stephan et al., 2000). We analysed neural connectivity using several graph-theoretical measures to capture global properties of the derived network, and found that Markov Centrality provides the most direct link between structure and function. With this registration approach, users can query the CoCoMac database by specifying spatial coordinates. Availability of deformation tools and homology evidence then allow one to directly attribute detailed anatomical animal data to human experimental results., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

16. Networks, noise and models: reconceptualizing the brain as a complex, distributed system.

Author

Breakspear M and McIntosh AR

Subjects

Algorithms, Brain anatomy & histology, Data Interpretation, Statistical, Electroencephalography, Humans, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging, Neural Pathways anatomy & histology, Neural Pathways physiology, Nonlinear Dynamics, Brain physiology, Models, Neurological, Nerve Net physiology

Published

2011

17. Moment-to-moment signal variability in the human brain can inform models of stochastic facilitation now.

Author

Garrett DD, McIntosh AR, and Grady CL

Subjects

Animals, Humans, Models, Neurological, Neurons physiology, Nonlinear Dynamics

Published

2011

18. Extracting message inter-departure time distributions from the human electroencephalogram.

Author

Mišić B, Vakorin VA, Kovačević N, Paus T, and McIntosh AR

Subjects

Cerebral Cortex physiology, Child, Cluster Analysis, Female, Humans, Least-Squares Analysis, Male, Telecommunications, Electroencephalography, Models, Neurological, Wavelet Analysis

Abstract

The complex connectivity of the cerebral cortex is a topic of much study, yet the link between structure and function is still unclear. The processing capacity and throughput of information at individual brain regions remains an open question and one that could potentially bridge these two aspects of neural organization. The rate at which information is emitted from different nodes in the network and how this output process changes under different external conditions are general questions that are not unique to neuroscience, but are of interest in multiple classes of telecommunication networks. In the present study we show how some of these questions may be addressed using tools from telecommunications research. An important system statistic for modeling and performance evaluation of distributed communication systems is the time between successive departures of units of information at each node in the network. We describe a method to extract and fully characterize the distribution of such inter-departure times from the resting-state electroencephalogram (EEG). We show that inter-departure times are well fitted by the two-parameter Gamma distribution. Moreover, they are not spatially or neurophysiologically trivial and instead are regionally specific and sensitive to the presence of sensory input. In both the eyes-closed and eyes-open conditions, inter-departure time distributions were more dispersed over posterior parietal channels, close to regions which are known to have the most dense structural connectivity. The biggest differences between the two conditions were observed at occipital sites, where inter-departure times were significantly more variable in the eyes-open condition. Together, these results suggest that message departure times are indicative of network traffic and capture a novel facet of neural activity.

Published

2011

19. Towards the virtual brain: network modeling of the intact and the damaged brain.

Author

Jirsa VK, Sporns O, Breakspear M, Deco G, and McIntosh AR

Subjects

Animals, Brain anatomy & histology, Humans, Nerve Net physiology, Neural Pathways physiology, Nonlinear Dynamics, Brain physiology, Brain Injuries pathology, Brain Injuries physiopathology, Brain Mapping, Models, Neurological, User-Computer Interface

Abstract

Neurocomputational models of large-scale brain dynamics utilizing realistic connectivity matrices have advanced our understanding of the operational network principles in the brain. In particular, spontaneous or resting state activity has been studied on various scales of spatial and temporal organization including those that relate to physiological, encephalographic and hemodynamic data. In this article we focus on the brain from the perspective of a dynamic network and discuss the role of its network constituents in shaping brain dynamics. These constituents include the brain's structural connectivity, the population dynamics of its network nodes and the time delays involved in signal transmission. In addition, no discussion of brain dynamics would be complete without considering noise and stochastic effects. In fact, there is mounting evidence that the interaction between noise and dynamics plays an important functional role in shaping key brain processes. In particular, we discuss a unifying theoretical framework that explains how structured spatio-temporal resting state patterns emerge from noise driven explorations of unstable or stable oscillatory states. Embracing this perspective, we explore the consequences of network manipulations to understand some of the brain's dysfunctions, as well as network effects that offer new insights into routes towards therapy, recovery and brain repair. These collective insights will be at the core of a new computational environment, the Virtual Brain, which will allow flexible incorporation of empirical data constraining the brain models to integrate, unify and predict network responses to incipient pathological processes.

Published

2010

20. The development of a noisy brain.

Author

McIntosh AR, Kovacevic N, Lippe S, Garrett D, Grady C, and Jirsa V

Subjects

Acoustic Stimulation methods, Adolescent, Adult, Age Factors, Animals, Brain blood supply, Child, Child Development, Electroencephalography methods, Humans, Infant, Magnetic Resonance Imaging methods, Nerve Net blood supply, Nerve Net physiology, Photic Stimulation methods, Time Factors, Brain growth & development, Brain Mapping, Models, Neurological, Noise, Nonlinear Dynamics

Abstract

Early in life, brain development carries with it a large number of structural changes that impact the functional interactions of distributed neuronal networks. Such changes enhance information processing capacity, moving the brain from a deterministic system to one that is more stochastic. The evidence from empirical studies with EEG and functional MRI suggests that this stochastic property is a result of an increased number of possible functional network configurations for a given situation. This is captured in the variability of endogenous and evoked responses or "brain noise ". In empirical data from infants and children, brain noise increases with maturation and correlates positively with stable behavior and accuracy. The noise increase is best explained through increased noise from network level interactions with a concomitant decrease of local noise. In old adults, brain noise continues to change, although the pattern of changes is not as global as in early development. The relation between high brain noise and stable behavior is maintained, but the relationships differ by region, suggesting changes in local dynamics that then impact potential network configurations. These data, when considered in concert with our extant modeling work, suggest that maturational changes in brain noise represent the enhancement offunctional network potential--the brain's dynamic repertoire.

Published

2010

21. Overview: integrating computational, cognitive and clinical expertise to understand brain network recovery.

Author

McIntosh AR, Ghilardi F, and Sporns O

Subjects

Nerve Net physiology, Neural Pathways anatomy & histology, Brain anatomy & histology, Brain physiology, Cognition physiology, Computer Simulation, Models, Neurological, Neural Pathways physiology

Published

2010

22. The effects of physiologically plausible connectivity structure on local and global dynamics in large scale brain models.

Author

Knock SA, McIntosh AR, Sporns O, Kötter R, Hagmann P, and Jirsa VK

Subjects

Animals, Brain anatomy & histology, Computer Graphics, Computer Simulation, Humans, Principal Component Analysis, Time Factors, Brain physiology, Brain Mapping, Models, Neurological, Nerve Net physiology, Neural Pathways physiology, Nonlinear Dynamics

Abstract

Functionally relevant large scale brain dynamics operates within the framework imposed by anatomical connectivity and time delays due to finite transmission speeds. To gain insight on the reliability and comparability of large scale brain network simulations, we investigate the effects of variations in the anatomical connectivity. Two different sets of detailed global connectivity structures are explored, the first extracted from the CoCoMac database and rescaled to the spatial extent of the human brain, the second derived from white-matter tractography applied to diffusion spectrum imaging (DSI) for a human subject. We use the combination of graph theoretical measures of the connection matrices and numerical simulations to explicate the importance of both connectivity strength and delays in shaping dynamic behaviour. Our results demonstrate that the brain dynamics derived from the CoCoMac database are more complex and biologically more realistic than the one based on the DSI database. We propose that the reason for this difference is the absence of directed weights in the DSI connectivity matrix.

Published

2009

23. A dual role for prediction error in associative learning.

Author

den Ouden HE, Friston KJ, Daw ND, McIntosh AR, and Stephan KE

Subjects

Acoustic Stimulation, Adult, Conditioning, Psychological physiology, Female, Humans, Male, Photic Stimulation, Young Adult, Association Learning physiology, Cognition physiology, Magnetic Resonance Imaging, Models, Neurological, Neuronal Plasticity physiology

Abstract

Confronted with a rich sensory environment, the brain must learn statistical regularities across sensory domains to construct causal models of the world. Here, we used functional magnetic resonance imaging and dynamic causal modeling (DCM) to furnish neurophysiological evidence that statistical associations are learnt, even when task-irrelevant. Subjects performed an audio-visual target-detection task while being exposed to distractor stimuli. Unknown to them, auditory distractors predicted the presence or absence of subsequent visual distractors. We modeled incidental learning of these associations using a Rescorla-Wagner (RW) model. Activity in primary visual cortex and putamen reflected learning-dependent surprise: these areas responded progressively more to unpredicted, and progressively less to predicted visual stimuli. Critically, this prediction-error response was observed even when the absence of a visual stimulus was surprising. We investigated the underlying mechanism by embedding the RW model into a DCM to show that auditory to visual connectivity changed significantly over time as a function of prediction error. Thus, consistent with predictive coding models of perception, associative learning is mediated by prediction-error dependent changes in connectivity. These results posit a dual role for prediction-error in encoding surprise and driving associative plasticity.

Published

2009

24. Testing effective connectivity changes with structural equation modeling: what does a bad model tell us?

Author

Protzner AB and McIntosh AR

Subjects

Algorithms, Computer Simulation, Humans, Brain Mapping, Models, Neurological, Models, Statistical, Nerve Net physiology

Abstract

Structural equation modeling (SEM) is a statistical method that can assess changes in effective connectivity across tasks or between groups. In its initial application to neuroimaging data, anatomical connectivity provided the constraints to decompose interregional covariances to estimate effective connections. There have been concerns expressed, however, with the validity of interpreting effective connections for a model that does not adequately fit the data. We sought to address this concern by creating two population networks with different patterns of effective connectivity, extracting three samples sizes (N = 100, 60, 20), and then assessing whether the ability to detect effective connectivity differences depended on absolute model fit. Four scenarios were assessed: (1) elimination of a region showing no task differences; (2) elimination of connections with no task differences; (3) elimination of connections that carried task differences, but could be expressed through alternative indirect routes; (4) elimination of connections that carried task differences, and could not be expressed through indirect routes. We were able to detect task differences in all four cases, despite poor absolute model fit. In scenario 3, total effects captured the overall task differences even though the direct effect was no longer present. In scenario 4, task differences that were included in the model remained, but the missing effect was not expressed. In conclusion, it seems that when independent information (e.g., anatomical connectivity) is used to define the causal structure in SEM, inferences about task- or group-dependent changes are valid regardless of absolute model fit., ((c) 2006 Wiley-Liss, Inc.)

Published

2006

25. Contexts and catalysts: a resolution of the localization and integration of function in the brain.

Author

McIntosh AR

Subjects

Animals, Brain diagnostic imaging, Cognition physiology, Humans, Neural Pathways diagnostic imaging, Radiography, Brain physiology, Brain Mapping, Models, Neurological, Neural Pathways physiology, Neuronal Plasticity physiology

Abstract

There has been a historical tension between theories of brain function emphasizing regional specialization and those focusing on integration across regions. This tension continues despite the pervasive use of functional neuroimaging, which enables testing of these theories in the human brain. There are instances of agreement, where regions thought to be critical for a given behavior (e.g., Broca's area and language production) do become more active when a person engages in that behavior. However, a number of disconcerting results have also been found. These include activation in areas not thought to be important for the behavior, and lack of activation in regions thought to be critical for particular behaviors based on studies of the damaged brain. A recently proposed Neural Context hypothesis of brain function provides a mechanism that can reconcile these apparently disparate findings. The hypothesis states that the functional relevance of a brain area depends on the status of other connected areas i.e., the context within which the region is operating. A region can participate in several behaviors through variations in its interactions with other areas. It is possible that certain critical nodes serve as Behavioural Catalysts, enabling the transition between behavioral states, without differential alterations in the measured activity. By virtue of its anatomical connections, an area could facilitate a shift in functional connectivity between one set of regions to another. An imaging study on the changing interregional interactions involving the hippocampus in learning and awareness serves as an example of neural context. In this case, the hippocampus may serve to catalyze the transition to awareness.

Published

2004

26. Towards a network theory of cognition.

Author

McIntosh AR

Subjects

Association Learning physiology, Brain Mapping, Humans, Mental Processes physiology, Neurons physiology, Brain physiology, Cognition physiology, Models, Neurological, Models, Psychological, Nerve Net physiology

Abstract

For cognitive neuroscience to go forward a more explicit effort is needed to use neurophysiology to constrain how the brain produces human mental functions. This review begins with the suggestion that two fundamental features may be critical for this effort. The first is the connectivity of the brain, which occupies an intermediate position between complete redundant interconnections and independence. The term semniconnected is presented as a designation, which is an obvious derivation of the term semiconductors as used in engineering. The second is transient response plasticity where a given neuron or collection of neurons may show rapid changes in response characteristics depending on experience. Response plasticity is a ubiquitous property of the brain rather than a unique characteristic of "neurocognitive" regions. These two properties may be brought together when brain areas interact such that their aggregate function embodies cognition. Three examples are used to illustrate these general principles and to develop the idea that a particular region in isolation may not act as a reliable index for a particular cognitive function. Instead, the neural context in which an area is active may define the cognitive function. Neural context emphasizes that the particular spatiotemporal pattern of neural interactions may hold the key to bridge between brain and mind.

Published

2000

27. Functional interactions between the medial temporal lobes and posterior neocortex related to episodic memory retrieval.

Author

Köhler S, McIntosh AR, Moscovitch M, and Winocur G

Subjects

Brain Mapping, Dominance, Cerebral physiology, Feedback, Humans, Male, Neural Pathways physiology, Cerebral Cortex physiology, Memory physiology, Models, Neurological, Temporal Lobe physiology

Abstract

We applied structural equation modeling to positron emission tomography data in humans to examine functional interactions between the right medial temporal lobe (MTL) and selected right neocortical regions in relation to visual recognition memory. Using a priori knowledge about anatomical connections between these regions as a guiding constraint, we modeled the pattern of interactions [i.e. covariances in regional cerebral blood flow (rCBF)] associated with episodic memory retrieval of spatial location and compared it with the pattern for retrieval of object identity. We also compared these patterns with those associated with perceptual matching of spatial location and object identity. Although displaying no difference in average rCBF across tasks, the right MTL showed domain-specific qualitative differences in interactions with posterior dorsal (parieto-occipital sulcus, supramarginal gyrus) and ventral regions (fusiform gyrus, superior temporal sulcus) but not with a prefrontal region. MTL interactions involving dorsal regions were positive in the spatial retrieval task but negative for object retrieval. Interactions involving ventral regions showed the reverse pattern. No comparable changes were observed during perceptual matching. Using control models, we demonstrated the neuroanatomical specificity of these results. Our results provide support for the notion that the nature of interactions between the MTL and posterior neocortex depends on the domain of information to-be-recovered.

Published

1998

28. Structural modeling of functional visual pathways mapped with 2-deoxyglucose: effects of patterned light and footshock.

Author

McIntosh AR and Gonzalez-Lima F

Subjects

Animals, Autoradiography, Carbon Radioisotopes, Darkness, Electroshock, Geniculate Bodies anatomy & histology, Geniculate Bodies physiology, Male, Photic Stimulation, Rats, Rats, Inbred Strains, Deoxyglucose metabolism, Models, Neurological, Visual Cortex anatomy & histology, Visual Cortex physiology, Visual Pathways anatomy & histology, Visual Pathways physiology

Abstract

This paper describes the first application of structural modeling to the visual system. Structural modeling, or path analysis, is a mathematical method that allows for the quantification of the functional strengths of anatomical connections between the structures that form a neural system. The objective was to demonstrate how structural modeling can be used to determine the functional interrelationships between brain structures that form the visual system and how these interrelationships change under different conditions. Data were obtained from measures of 2-deoxyglucose uptake in the visual system of rats presented with either patterned light or darkness. The effects of arousing footshock on visual system operations were also investigated. Models based on the anatomical connections and the interregional correlations between metabolic activity data were used to determine path coefficients representing the magnitude of the influence of each directional path. Statistical evaluation of the models revealed that the dominant positive influences on visual system activity in the darkness were the tectocortical subsystem and the descending connections from secondary visual cortex. In the patterned light model, the total influence of the geniculocortical subsystem was higher than in the dark, and the tectocortical pathways showed both a reduction and a shift in the direction of effects. The models also revealed that the effects of footshock-induced arousal on visual system operations depended upon the visual environment and on extra-visual influences. The footshock led to an increase in the interaction of the two main subsystems at the level of connections between primary visual cortex and the lateral posterior nucleus, and a descending negative influence from the secondary visual cortex became dominant. The models are discussed in the context of conventional analyses to show how structural modeling allows for the determination of much more information about the functional interactions within the visual system of subjects under different experimental conditions.

Published

1992

29. Structural modeling of functional neural pathways mapped with 2-deoxyglucose: effects of acoustic startle habituation on the auditory system.

Author

McIntosh AR and Gonzalez-Lima F

Subjects

Acoustic Stimulation, Animals, Brain Mapping methods, Deoxyglucose, Rats, Auditory Pathways physiology, Habituation, Psychophysiologic physiology, Models, Neurological, Models, Structural, Reflex, Startle physiology

Abstract

This paper describes the first application of structural modeling to neuroscience. Structural modeling (also known as path analysis) is a method to assess the relative impact of directional links in a system and how these interrelations may change under different conditions. The objective was to demonstrate how structural modeling can be used to determine the functional interrelationships between brain structures that form the auditory system. Using structural modeling, changes in auditory system 2-DG uptake were examined during long- and short-term habituation of the acoustic startle reflex. Models were based on the anatomical connections between central auditory system structures. Using functional 2-DG data, the correlations between these structures were calculated and numerical weights were computed for each anatomical link. The analysis revealed that the lemniscal path was dominant during short-term habituation, while during long-term habituation this influence was modified through extra-lemniscal pathways. The models are discussed in the context of previous findings to demonstrate how structural modeling can not only complement, but also extract more information from 2-DG mapping experiments.

Published

1991