MedPath

" Virtual Brain "-Based Interpretation of Electrophysiological Signals in Epilepsy

Not Applicable
Completed
Conditions
Epilepsy
Interventions
Device: MRI scanning
Registration Number
NCT02603640
Lead Sponsor
Assistance Publique Hopitaux De Marseille
Brief Summary

Epilepsy is a major neurological disorder, affecting of the order of 0.5 to 1% of the population. It is a very invalidating disease, with high impact on quality of life. In a large proportion of cases, medication cannot prevent seizures; surgical removal of the regions responsible for seizures is then the only way to cure patients. However, results crucially depend on the correct delineation of the epileptogenic zone.

In this context, computational modeling, under the form of a "virtual brain" is a powerful tool to investigate the impact of different configurations of the sources on the measures, in a well-controlled environment.

In this project, the simulate in a biologically realistic way MEG (Magnetoencephalography) and EEG (Electroencephalography) fields produced by different configurations of brain sources, which will differ in terms of spatial and dynamic characteristics will be offered to participants. The research hypothesis is that computational and biophysical models can bring crucial information to clinically interpret the signals measured by MEG and EEG. In particular, the hypothesis can help to efficiently address some complementary questions faced by epileptologists when analyzing electrophysiological data.

The strategy will be three-fold:

i) Construct a virtual brain models with both dynamic aspects (reproducing both hyperexcitability and hypersynchronisation alterations observed in the epileptic brain) and a realistic geometry based on actual tractography measures performed in patients ii) Explore the parameter space though large-scale simulations of source configurations, using parallel computing implemented on a computer cluster.

iii) Confront the results of these simulations to simultaneous recordings of EEG, MEG and intracerebral EEG (stereotactic EEG, stereoelectroencephalography (SEEG)). The models will be tuned on SEEG signals, and tested versus the surface signals in order to validate the ability of the models to represent real MEG and EEG signals.

The project constitutes a translational effort from theoretical neuroscience and mathematics towards clinical investigation. A first output of the project will be a database of simulations, which will permit in a given situation to assess the number of configurations that could have given rise to the observed signals in EEG, MEG and SEEG. A second - and major - output of the project will be to give the clinician access to a software platform which will allow for testing possible configurations of hyperexcitable regions in a user-friendly way. Moreover, representative examples will be made available to the community through a website, which will permit its use in future studies aimed at confronting the results of different signal processing methods on the same 'ground truth' data.

Detailed Description

Not available

Recruitment & Eligibility

Status
COMPLETED
Sex
All
Target Recruitment
20
Inclusion Criteria
  • Epilepsy patients with planned intracerebral exploration (SEEG)
  • informed patient
  • patient affiliated to French social security
Exclusion Criteria
  • Patients under 18
  • Pregnant or breastfeeding women
  • Patients deprived of liberty by legal decision
  • Patients not covered by social security
  • Patients who did not sign informed consent
  • patients who cannot undertake MRI exam

Study & Design

Study Type
INTERVENTIONAL
Study Design
SINGLE_GROUP
Arm && Interventions
GroupInterventionDescription
epileptic patientMRI scanning-
Primary Outcome Measures
NameTimeMethod
recordings Magnetoencephalography (MEG)36 months

The number of events per sensor

recordings Stereoelectroencephalography (SEEG)36 months

The number of events per sensor

Determining regions responsible epileptic discharges36 months

Diffusion MRI

recordings Electroencephalography (EEG)36 months

The number of events per sensor

Secondary Outcome Measures
NameTimeMethod

Trial Locations

Locations (1)

Assistance Publique Hôpitaux de Marseille

🇫🇷

Marseille, France

Related Trials

Efficacy of 128-channel EEG Combined With BESA Dipole Localization and Intervention on Brain Waves for Epilepsy

CompletedNot Applicable
Shanghai Zhongshan Hospital
Posted 11/24/2015
Updated 2/25/2020

Priming the Epileptic Brain: tVNS to Improve Efficacy of add-on AED in Patients With Focal Epilepsy

Unknown StatusNot Applicable
Eindhoven University of Technology
Posted 1/6/2022

Functional Study of Inhibitory Neurotransmission in the Human Epileptic Brain.

Recruiting
Neuromed IRCCS
Posted 7/14/2022
Updated 8/2/2022

Electroclinical Correlates in Essential Tremor

RecruitingNot Applicable
University Hospital, Bordeaux
Posted 1/5/2023
Updated 11/1/2024

The Role of Intracranial Electroencephalography (IEEG) in the Localization of Epileptogenic Zones (EZ) and Its Relationship With Prognosis

Recruiting
Second Affiliated Hospital, School of Medicine, Zhejiang University
Posted 7/5/2022

Contribution of Genetics, Non-invasive Methods and Neuropsychology in Focal Cryptogenic Epilepsies

CompletedNot Applicable
IRCCS Eugenio Medea
Posted 8/20/2021
Updated 5/1/2025
© Copyright 2025. All Rights Reserved by MedPath
HomeTerms & ConditionsPrivacy Policy