Dynamic Causal Modeling on the Identification of Interacting Networks in the Brain: A Systematic Review

Wang, Duojin; Liang, Sailan

doi:10.1109/tnsre.2021.3123964

Cited by 3 publications

(4 citation statements)

References 189 publications

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“…The source-specific, four-population neural mass models (Figure 1E) generated power spectral densities (PSD) (1-60Hz, 1Hz steps) with very good fit for most iEEG recordings with few exceptions (2.4% (42/1770) electrode contacts showed a noticeable error; frequency fit: MSE median = 1.04*10 -6 and mode = 1.29*10 -11 ) (Figure 1F). In addition, the modelled PSDs match previously reported profiles (54)(55)(56) and showed characteristic lobe-specific features such as an alpha peak in the occipital lobe (Figure 1C), but also indicated high intra-region and inter-subject variability (Figure 1D). The canonical microcircuit model with four neural populations, which approximate cortical layer-specific activity, was used to model iEEG in the frequency domain.…”

Section: Neuronal Population Models Explain Regional Oscillatory Brai...supporting

confidence: 86%

“…A possible computational approach to integrate both iEEG and neuroreceptor data and to thereby provide neurobiological grounding, is to incorporate the receptor features as prior information to model fitting of electrophysiological recordings. Bayesian approaches such as dynamic causal modelling (DCM) (50,51) (50)(51)(52)(53)(54)(55)(56) allow for this integration of empirically derived priors (57,58), which enables us to evaluate different hypotheses about how neuroreceptor composition contributes to regional oscillatory signatures (iEEG).…”

Section: Introductionmentioning

confidence: 99%

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Topographic variation in neurotransmitter receptor densities explains differences in intracranial EEG spectra

Stoof,

Friston,

Tisdall

et al. 2024

Preprint

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Neurotransmitter receptor expression and neuronal population dynamics show regional variability across the human cortex. However, currently there is an explanatory gap regarding how cortical microarchitecture and mesoscopic electrophysiological signals are mechanistically related, limiting our ability to exploit these measures of brain (dys)function for improved treatments of brain disorder; e.g., epilepsy. To bridge this gap, we leveraged dynamic causal modelling (DCM) and fitted biophysically informed neural mass models to a normative set of intracranial EEG data. Subsequently, using a hierarchical Bayesian modelling approach, we evaluated whether model evidence improved when information about regional neurotransmitter receptor densities is provided. We then tested whether the inferred constraints - furnished by receptor density - generalise across different electrophysiological recording modalities. The neural mass models explained regionally specific intracranial EEG spectra accurately, when fitted independently. Incorporating prior information on receptor distributions, further improved model evidence, indicating that variability in receptor density explains some variance in cortical population dynamics. The output of this modelling provides a cortical atlas of neurobiologically informed intracortical synaptic connectivity parameters that can be used as empirical priors in future - e.g., patient specific - modelling, as demonstrated in a worked example (a single-subject mismatch negativity study). In summary, we show that molecular cortical characteristics (i.e., receptor densities) can be incorporated to improve generative, biophysically plausible models of coupled neuronal populations. This work can help to explain regional variations in human electrophysiology, may provide a methodological foundation to integrate multi-modal data, and might serve as a normative resource for future DCM studies of electrophysiology.

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Section: Neuronal Population Models Explain Regional Oscillatory Brai...supporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Topographic variation in neurotransmitter receptor densities explains differences in intracranial EEG spectra

Stoof,

Friston,

Tisdall

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…used the normal form of a Hopf bifurcation to simulate the state changes of a single brain node and analyzed the changes in resting‐state functional connectivity (FC) in the whole brain during AD progression. The dynamic causal model (DCM), a directed model, can describe differences in neuronal signals over time, providing a powerful and intuitive analytical tool for functional network simulation based on structural networks [9,10] …”

Section: Introductionmentioning

confidence: 99%

“…The dynamic causal model (DCM), a directed model, can describe differences in neuronal signals over time, providing a powerful and intuitive analytical tool for functional network simulation based on structural networks. [9,10] Most existing control schemes use state reproduction to adjust the system state by directly adjusting the parameter values in the model. [11] The control parameters cannot be automatically adjusted in real-time according to the status of the nodes and the system.…”

Section: Introductionmentioning

confidence: 99%

Target localization intervention and prognosis evaluation for an individual with mild cognitive impairment

Wang,

Zhao,

et al. 2023

Brain-X

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Currently, no specific treatments are available for Alzheimer's disease (AD). Mild cognitive impairment (MCI), the preclinical stage of AD, has a high possibility of reversing symptoms through neural regulation. A state dynamics model for single brain regions was developed to simulate blood oxygen level‐dependent signals in a patient with early mild cognitive impairment. Subsequently, the analysis of functional connections was used to comprehensively consider multiple complex network centralities to locate the intervention targets, and a multiple brain region collaborative control scheme was designed. Finally, the reliability and effectiveness of the intervention were verified at the brain region and subnetwork levels. This technique provides a basis for future clinical diagnosis and treatment of AD and MCI.

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A strategy of model space search for dynamic causal modeling in task fMRI data exploratory analysis

Dai

Zhou

et al. 2022

Phys Eng Sci Med

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Dynamic Causal Modeling on the Identification of Interacting Networks in the Brain: A Systematic Review

Cited by 3 publications

References 189 publications

Topographic variation in neurotransmitter receptor densities explains differences in intracranial EEG spectra

Topographic variation in neurotransmitter receptor densities explains differences in intracranial EEG spectra

Target localization intervention and prognosis evaluation for an individual with mild cognitive impairment

A strategy of model space search for dynamic causal modeling in task fMRI data exploratory analysis

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