A new neuroinformatics approach to personalized medicine in neurology: The Virtual Brain

Falcon, Maria Inez; Jirsa, Viktor K.; Solodkin, Ana

doi:10.1097/wco.0000000000000344

Cited by 55 publications

(55 citation statements)

References 54 publications

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“…In the current study, we conducted a large parameter space exploration with TVB, simulating BOLD fMRI and electrophysiological neural signals for 50 individual human brains. TVB has previously been used to study how neural networks behave in healthy and diseased states (8,10,13,18,21,26). Here, we assert that goodness-of-fit of simulated to empirical data converge at a particular parameter set across multiple tenets of the EEG and fMRI signal, and that there are reliable inter-individual differences in biophysical parameters that lead to optimal functioning.…”

Section: Discussionmentioning

confidence: 92%

“…In a second set of simulations, we explored a narrower range of global coupling and reproduced alpha frequency (8)(9)(10)(11)(12)(13)(14)(15) Hz) oscillations in the neural signal, a characteristic feature of human empirical EEG (37,38), which has previously been modelled as a function of global coupling in MEG (30). Here, it was shown that transmission delays and global cortical coupling affect the mean power in an MEG model, and the best model fit was found in the alpha band power.…”

Section: Role Of Biophysical Parameters For Frequency and Alpha Bimodmentioning

confidence: 92%

“…Optimal model fit (simulated FC to empirical FC) is highly dependent on the global coupling and conduction speed values. (8,9,13,18,(20)(21)(22)(23). See equation 1 in Methods for a mathematical description of these parameters.…”

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confidence: 99%

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Fifty shades of The Virtual Brain: Converging optimal working points yield biologically plausible electrophysiological and imaging features

Triebkorn

Zimmermann

Stefanovski

et al. 2020

Preprint

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Using The Virtual Brain (TVB, thevirtualbrian.org) simulation platform, we explored for 50 individual adult human brains (ages 18-80), how personalized connectome based brain network modelling captures various empirical observations as measured by functional magnetic resonance imaging (fMRI) and electroencephalography (EEG). We compare simulated activity based on individual structural connectomes (SC) inferred from diffusion weighted imaging with fMRI and EEG in the resting state. We systematically explore the role of the following model parameters:conduction velocity, global coupling and graph theoretical features of individual SC. First, a subspace of the parameter space is identified for each subject that results in realistic brain activity, i.e. reproducing the following prominent features of empirical EEG-fMRI activity: topology of resting-state fMRI functional connectivity (FC), functional connectivity dynamics (FCD), electrophysiological oscillations in the delta (3-4 Hz) and alpha (8-12 Hz) frequency range and their bimodality, i.e. low and high energy modes. Interestingly, FCD fit, bimodality and static FC fit are highly correlated. They all show their optimum in the same range of global coupling. In other words, only when our local model is in a bistable regime we are able to generate switching of modes in our global network. Second, our simulations reveal the explicit network mechanisms that lead to electrophysiological oscillations, their bimodal behaviour and inter-regional differences. Third, we discuss biological interpretability of the Stefanescu-Jirsa-Hindmarsh-Rose-3D model when embedded inside the large-scale brain network and mechanisms underlying the emergence of bimodality of the neural signal.With the present study, we set the cornerstone for a systematic catalogue of spatiotemporal brain activity regimes generated with the connectome-based brain simulation platform The Virtual Brain. Author SummaryIn order to understand brain dynamics we use numerical simulations of brain network models. Combining the structural backbone of the brain, that is the white matter fibres connecting distinct regions in the grey matter, with dynamical systems describing the activity of neural populations we are able to simulate brain function on a large scale. In order to make accurate prediction with this network, it is crucial to determine optimal model parameters. We here use an explorative approach to adjust model parameters to individual brain activity, showing that subjects have their own optimal point in the parameter space, depending on their brain structure and function. At the same time, we investigate the relation between bistable phenomena on the scale of neural populations and the changed in functional connectivity on the brain network scale. Our results are important for future modelling approaches trying to make accurate predictions of brain function.Brain network models allow us to investigate how realistic neural behaviour arises as a function of variations in specific neural parameters. Large-sc...

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Section: Discussionmentioning

confidence: 92%

Section: Role Of Biophysical Parameters For Frequency and Alpha Bimodmentioning

confidence: 92%

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Fifty shades of The Virtual Brain: Converging optimal working points yield biologically plausible electrophysiological and imaging features

Triebkorn

Zimmermann

Stefanovski

et al. 2020

Preprint

Self Cite

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“…Previous work has shown that biophysical parameters derived from TVB modeling can describe healthy neural dynamics (Jirsa et al, 2010;Kunze et al, 2016;Roy et al, 2014), as well as disease. As a proof of concept, it has been shown that these biophysical parameters correlate with motor recovery from stroke (Adhikari et al, 2015;Falcon et al, 2016a;Falcon et al, 2016b;Falcon et al, 2015), and the generation of epileptic seizures , along with seizure progression (Jirsa et al, 2017). The biophysical parameters derived from TVB modeling have been shown to correlate with a variety of clinical phenotypes, and as such offer a potential for translation to clinical applications.…”

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confidence: 99%

Differentiation of Alzheimer’s disease based on local and global parameters in personalized Virtual Brain models

Zimmermann

Perry

Breakspear

et al. 2018

Preprint

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Alzheimer's disease (AD) is marked by cognitive dysfunction emerging from neuropathological processes impacting brain function. AD affects brain dynamics at the local level, such as changes in the balance of inhibitory and excitatory neuronal populations, as well as long-range changes to the global network. Individual differences in these changes as they relate to behaviour are poorly understood. Here, we use a multi-scale neurophysiological model, "The Virtual Brain (TVB)", based on empirical multi-modal neuroimaging data, to study how local and global dynamics correlate with individual differences in cognition. In particular, we modeled individual resting-state functional activity of 124 individuals across the behavioral spectrum from healthy aging, to amnesic Mild Cognitive Impairment (MCI), to AD. The model parameters required to accurately simulate empirical functional brain imaging data correlated significantly with cognition, and exceeded the predictive capacity of empirical connectomes.

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“…However, this cannot be taken for granted in surrogates obtained from models fitted to individual 310 patients, where higher inter-subject variability may arise from abnormalities in brain structure and function. Since these limitations could be informative of such abnormalities, low dimensional whole-brain models should be further ex-plored in the context of reproducing single subject FC from the individual SC of the patients [24].…”

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confidence: 99%

Data augmentation based on dynamical systems for the classification of brain states

Perl

Pallavicini

Ipiña

et al. 2020

Preprint

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The application of machine learning algorithms to neuroimaging data shows great promise for the classification of physiological and pathological brain states.However, classifiers trained on high dimensional data are prone to overfitting, especially for a low number of training samples. We describe the use of wholebrain computational models for data augmentation in brain state classification. Our low dimensional model is based on nonlinear oscillators coupled by the empirical SC of the brain. We use this model to enhance a dataset consisting of functional magnetic resonance imaging recordings acquired during all stages of the human wake-sleep cycle. After fitting the model to the average FC of each state, we show that the synthetic data generated by the model yields classification accuracies comparable to those obtained from the empirical data. enough information to train classifiers that present significant transfer learning accuracy to the whole sample. Whole-brain computational modeling represents a useful tool to produce large synthetic datasets for data augmentation in the classification of certain brain states, with potential applications to computerassisted diagnosis and prognosis of neuropsychiatric disorders.

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A new neuroinformatics approach to personalized medicine in neurology: The Virtual Brain

Cited by 55 publications

References 54 publications

Fifty shades of The Virtual Brain: Converging optimal working points yield biologically plausible electrophysiological and imaging features

Fifty shades of The Virtual Brain: Converging optimal working points yield biologically plausible electrophysiological and imaging features

Differentiation of Alzheimer’s disease based on local and global parameters in personalized Virtual Brain models

Data augmentation based on dynamical systems for the classification of brain states

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