A hierarchical anatomical framework and workflow for organizing stereotactic encephalography in epilepsy

A hierarchical anatomical framework and workflow for organizing stereotactic encephalography in epilepsy

Stereotactic electroencephalography (SEEG) is an increasingly utilized method for invasive monitoring in patients with medically intractable epilepsy. Yet, the lack of standardization for labeling electrodes hinders communication among clinicians. A rational clustering of contacts based on anatomy r...

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Veröffentlicht in:Human brain mapping 2022-11, Vol.43 (16), p.4852-4863
Hauptverfasser: Zheng, Bryan, Hsieh, Ben, Rex, Nathaniel, Lauro, Peter M., Collins, Scott A., Blum, Andrew S., Roth, Julie L., Ayub, Neishay, Asaad, Wael F.
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Sprache:eng
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Brain
Clustering
Convulsions & seizures
Drug Resistant Epilepsy - surgery
EEG
Electrodes
Electrodes, Implanted
Electroencephalography
Electroencephalography - methods
Electronic health records
Electronic medical records
Electrophysiology
Epilepsy
Epilepsy - diagnostic imaging
Epilepsy - surgery
Humans
Labeling
Labels
Magnetic resonance imaging
Medical imaging
neuroanatomy
Neuroimaging
neurophysiology
SEEG
Seizures
Seizures - diagnostic imaging
Seizures - surgery
Software
Standardization
Stereotaxic Techniques
Tomography
Workflow
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container_end_page 4863
container_issue 16
container_start_page 4852
container_title Human brain mapping
container_volume 43
creator Zheng, Bryan
Hsieh, Ben
Rex, Nathaniel
Lauro, Peter M.
Collins, Scott A.
Blum, Andrew S.
Roth, Julie L.
Ayub, Neishay
Asaad, Wael F.
description Stereotactic electroencephalography (SEEG) is an increasingly utilized method for invasive monitoring in patients with medically intractable epilepsy. Yet, the lack of standardization for labeling electrodes hinders communication among clinicians. A rational clustering of contacts based on anatomy rather than arbitrary physical leads may help clinical neurophysiologists interpret seizure networks. We identified SEEG electrodes on post‐implant CTs and registered them to preoperative MRIs segmented according to an anatomical atlas. Individual contacts were automatically assigned to anatomical areas independent of lead. These contacts were then organized using a hierarchical anatomical schema for display and interpretation. Bipolar‐referenced signal cross‐correlations were used to compare the similarity of grouped signals within a conventional montage versus this anatomical montage. As a result, we developed a hierarchical organization for SEEG contacts using well‐accepted, free software that is based solely on their post‐implant anatomical location. When applied to three example SEEG cases for epilepsy, clusters of contacts that were anatomically related collapsed into standardized groups. Qualitatively, seizure events organized using this framework were better visually clustered compared to conventional schemes. Quantitatively, signals grouped by anatomical region were more similar to each other than electrode‐based groups as measured by Pearson correlation. Further, we uploaded visualizations of SEEG reconstructions into the electronic medical record, rendering them durably useful given the interpretable electrode labels. In conclusion, we demonstrate a standardized, anatomically grounded approach to the organization of SEEG neuroimaging and electrophysiology data that may enable improved communication among and across surgical epilepsy teams and promote a clearer view of individual seizure networks. We developed a hierarchical organization for SEEG contacts using well‐accepted, free software that is based solely on their post‐implant anatomical location. Qualitatively, seizure events organized using this framework were better visually clustered compared to conventional schemes. Quantitatively, signals grouped by anatomical region were more similar to each other than electrode‐based groups as measured by Pearson correlation.
doi_str_mv 10.1002/hbm.26017
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Yet, the lack of standardization for labeling electrodes hinders communication among clinicians. A rational clustering of contacts based on anatomy rather than arbitrary physical leads may help clinical neurophysiologists interpret seizure networks. We identified SEEG electrodes on post‐implant CTs and registered them to preoperative MRIs segmented according to an anatomical atlas. Individual contacts were automatically assigned to anatomical areas independent of lead. These contacts were then organized using a hierarchical anatomical schema for display and interpretation. Bipolar‐referenced signal cross‐correlations were used to compare the similarity of grouped signals within a conventional montage versus this anatomical montage. As a result, we developed a hierarchical organization for SEEG contacts using well‐accepted, free software that is based solely on their post‐implant anatomical location. 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subjects Brain
Clustering
Convulsions & seizures
Drug Resistant Epilepsy - surgery
EEG
Electrodes
Electrodes, Implanted
Electroencephalography
Electroencephalography - methods
Electronic health records
Electronic medical records
Electrophysiology
Epilepsy
Epilepsy - diagnostic imaging
Epilepsy - surgery
Humans
Labeling
Labels
Magnetic resonance imaging
Medical imaging
neuroanatomy
Neuroimaging
neurophysiology
SEEG
Seizures
Seizures - diagnostic imaging
Seizures - surgery
Software
Standardization
Stereotaxic Techniques
Tomography
Workflow
title A hierarchical anatomical framework and workflow for organizing stereotactic encephalography in epilepsy
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