Intracranial EEG in the 21st Century.
Barbara C JobstFabrice BartolomeiBeate DiehlBirgit FrauscherPhilippe KahaneLorella MinottiAshwini SharanNastasia TardyGregory WorrellJean GotmanPublished in: Epilepsy currents (2020)
Intracranial electroencephalography (iEEG) has been the mainstay of identifying the seizure onset zone (SOZ), a key diagnostic procedure in addition to neuroimaging when considering epilepsy surgery. In many patients, iEEG has been the basis for resective epilepsy surgery, to date still the most successful treatment for drug-resistant epilepsy. Intracranial EEG determines the location and resectability of the SOZ. Advances in recording and implantation of iEEG provide multiple options in the 21st century. This not only includes the choice between subdural electrodes (SDE) and stereoelectroencephalography (SEEG) but also includes the implantation and recordings from microelectrodes. Before iEEG implantation, especially in magnetic resonance imaging -negative epilepsy, a clear hypothesis for seizure generation and propagation should be based on noninvasive methods. Intracranial EEG implantation should be planned by a multidisciplinary team considering epileptic networks. Recordings from SDE and SEEG have both their advantages and disadvantages. Stereo-EEG seems to have a lower rate of complications that are clinically significant, but has limitations in spatial sampling of the cortical surface. Stereo-EEG can sample deeper areas of the brain including deep sulci and hard to reach areas such as the insula. To determine the epileptogenic zone, interictal and ictal information should be taken into consideration. Interictal spiking, low frequency slowing, as well as high frequency oscillations may inform about the epileptogenic zone. Ictally, high frequency onsets in the beta/gamma range are usually associated with the SOZ, but specialized recordings with combined macro and microelectrodes may in the future educate us about onset in higher frequency bands. Stimulation of intracranial electrodes triggering habitual seizures can assist in identifying the SOZ. Advanced computational methods such as determining the epileptogenicity index and similar measures may enhance standard clinical interpretation. Improved techniques to record and interpret iEEG may in the future lead to a greater proportion of patients being seizure free after epilepsy surgery.
Keyphrases
- high frequency
- temporal lobe epilepsy
- functional connectivity
- resting state
- minimally invasive
- drug resistant
- working memory
- transcranial magnetic stimulation
- magnetic resonance imaging
- end stage renal disease
- ejection fraction
- newly diagnosed
- chronic kidney disease
- coronary artery bypass
- multidrug resistant
- prognostic factors
- peritoneal dialysis
- multiple sclerosis
- risk factors
- coronary artery disease
- acinetobacter baumannii
- current status
- computed tomography
- white matter
- cystic fibrosis
- surgical site infection
- brain injury
- patient reported
- gold nanoparticles
- atrial fibrillation
- percutaneous coronary intervention