Spatiotemporal forward solution of the EEG and MEG using network modeling

Jirsa, Viktor K.; Jantzen, Kelly J.; Fuchs, Armin; Kelso, J. A. Scott

doi:10.1109/tmi.2002.1009385

Cited by 135 publications

(108 citation statements)

References 60 publications

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“…In particular, neural field models (Amari, 1978;Jirsa and Haken, 1996;Nunez, 1974Robinson, 1997Wilson-Cowan, 1974) have a spatial symmetry in their connectivity, which is always reflected in the symmetry of the resulting neural source activations, even though it may be significantly less apparent (if at all) in the EEG and MEG space. This led to the conclusion that the integration of tractographic data is imperative for future large-scale brain modeling attempts ( Jirsa et al, 2002), since the symmetry of the connectivity will constrain the solutions of the neural sources.…”

Section: Forward Modelmentioning

confidence: 99%

The Virtual Brain Integrates Computational Modeling and Multimodal Neuroimaging

et al. 2013

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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 modelbased 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.

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Section: Forward Modelmentioning

confidence: 99%

The Virtual Brain Integrates Computational Modeling and Multimodal Neuroimaging

et al. 2013

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“…The local field potentials (or the "wave packets" as Freeman [97] names them), which are the unified mean-field potentials of neuronal assemblies generated by the synchronized activity of thousands of neurons in the extracellular space of the cortical sheet, are understood to generate the EEG [97,132]. The neuronal cell membranes, being good electrical insulators, guide the flow of both intracellular and extracellular currents and, thus, result in a current flow perpendicular to the cortical surface due to the perpendicular alignment and elongated shape of pyramidal neurons [194]. The neuronal assemble average of these currents results in the primary current density with the same waveform and mean frequency over the entire neuronal assembly [195].…”

Section: Macroscopic Level Of Brain Organizationmentioning

confidence: 99%

Natural world physical, brain operational, and mind phenomenal space–time

Fingelkurts

Neves

2010

Physics of Life Reviews

166

233

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Concepts of space and time are widely developed in physics. However, there is a considerable lack of biologically plausible theoretical frameworks that can demonstrate how space and time dimensions are implemented in the activity of the most complex life-system -the brain with a mind. Brain activity is organized both temporally and spatially, thus representing space-time in the brain. Critical analysis of recent research on the space-time organization of the brain's activity pointed to the existence of so-called operational space-time in the brain. This space-time is limited to the execution of brain operations of differing complexity. During each such brain operation a particular short-term spatio-temporal pattern of integrated activity of different brain areas emerges within related operational space-time. At the same time, to have a fully functional human brain one needs to have a subjective mental experience. Current research on the subjective mental experience offers detailed analysis of space-time organization of the mind. According to this research, subjective mental experience (subjective virtual world) has definitive spatial and temporal properties similar to many physical phenomena. Based on systematic review of the propositions and tenets of brain and mind space-time descriptions, our aim in this review essay is to explore the relations between the two. To be precise, we would like to discuss the hypothesis that via the brain operational space-time the mind subjective space-time is connected to otherwise distant physical space-time reality.Key words: spatial, temporal, consciousness, cognition, operation, architectonics, EEG, field, metastability, physics, coordinative dynamics, self-organization, cortex.

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“…Emanating from large ensembles of mutually interacting neurons, averaging methods like mean-field approaches result in weakly nonlinear mappings from action potentials to dendritic currents. Since the latter may be considered as generators of extracellular fields, ensemble or field-theoretical descriptions of the neocortex yield the macroscopic dynamics of distinct cortical areas as studied encephalographicallysee, e.g., Frank et al (2000) and Jirsa et al (2002) for recent discussions and explicit derivations. To capture the main aspects of pertinent data, however, we here abstain from such ensemble or field-theoretical approaches but simply assume that pulse rates and/or dendritic currents have oscillatory properties.…”

Section: Modeling Rhythmic Movementmentioning

confidence: 99%

“…Based on previous investigations of patterns of brain activity during the performance of unimanual and bimanual isofrequency tasks (Kelso et al 1992;Wallenstein et al 1995;Mayville et al 2001) and corresponding modeling work (e.g., Frank et al 2000;Jirsa et al 2002), it may be expected that the spatiotemporal brain activity patterns during multifrequency tasks can be described in terms of a few dynamical processes and their couplings. These couplings, which are brought about via inhibitory and excitatory inter-and intrahemispheric connections, are of essential importance because they may invoke entrained (i.e., coherent) activity distributions, both within and across hemispheres, as well as spontaneous transitions between such distributions.…”

Section: Introductionmentioning

confidence: 99%

Stabilization of bimanual coordination due to active interhemispheric inhibition: a dynamical account

2005

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Abstract. Based on recent brain-imaging data and congruent theoretical insights, a dynamical model is derived to account for the patterns of brain activity observed during stable performance of bimanual multifrequency patterns, as well as during behavioral instabilities in the form of phase transitions between such patterns. The model incorporates four dynamical processes, defined over both motor and premotor cortices, which are coupled through inhibitory and excitatory inter-and intrahemispheric connections. In particular, the model underscores the crucial role of interhemispheric inhibition in reducing the interference between disparate frequencies during stable performance, as well as the failure of this reduction during behavioral transitions. As an aside, the model also accounts for in-and antiphase preferences during isofrequency movements. The viability of the proposed model is illustrated by magnetoencephalographic signals that were recorded from an experienced subject performing a polyrhythmic tapping task that was designed to induce transitions between multifrequency patterns. Consistent with the model's dynamics, contra-and ipsilateral cortical areas of activation were frequency-and phase-locked, while their activation strength changed markedly in the vicinity of transitions in coordination.

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Spatiotemporal forward solution of the EEG and MEG using network modeling

Cited by 135 publications

References 60 publications

The Virtual Brain Integrates Computational Modeling and Multimodal Neuroimaging

The Virtual Brain Integrates Computational Modeling and Multimodal Neuroimaging

Natural world physical, brain operational, and mind phenomenal space–time

Stabilization of bimanual coordination due to active interhemispheric inhibition: a dynamical account

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