Robot-assisted Stereoelectroencephalography Electrode Placement in Twenty-three Pediatric Patients: a High-resolution Analysis of Individual Lead Placement Time and Accuracy at a Single Institution

Overview

Journal Childs Nerv Syst

Specialty Pediatrics

Date 2021 Mar 19

PMID 33738542

Citations 5

Authors

David J Bonda

Rachel Pruitt

Liana Theroux

Todd Goldstein

Dimitre G Stefanov

Sanjeev Kothare

Shefali Karkare

Shaun Rodgers

Affiliations

Soon will be listed here.

Abstract

Purpose: We describe a detailed evaluation of predictors associated with individual lead placement efficiency and accuracy for 261 stereoelectroencephalography (sEEG) electrodes placed for epilepsy monitoring in twenty-three children at our institution.

Methods: Intra- and post-operative data was used to generate a linear mixed model to investigate predictors associated with three outcomes (lead placement time, lead entry error, lead target error) while accounting for correlated observations from the same patients. Lead placement time was measured using electronic time-stamp records stored by the ROSA software for each individual electrode; entry and target site accuracy was measured using postoperative stereotactic CT images fused with preoperative electrode trajectory planning images on the ROSA computer software. Predictors were selected from a list of variables that included patient demographics, laterality of leads, anatomic location of lead, skull thickness, bolt cap device used, and lead sequence number.

Results: Twenty-three patients (11 female, 48%) of mean age 11.7 (± 6.1) years underwent placement of intracranial sEEG electrodes (median 11 electrodes) at our institution over a period of 1 year. There were no associated infections, hemorrhages, or other adverse events, and successful seizure capture was obtained in all monitored patients. The mean placement time for individual electrodes across all patients was 6.56 (± 3.5) min; mean target accuracy was 4.5 (± 3.5) mm. Lesional electrodes were associated with 25.7% (95% CI: 6.7-40.9%, p = 0.02) smaller target point errors. Larger skull thickness was associated with larger error: for every 1-mm increase in skull thickness, there was a 4.3% (95% CI: 1.2-7.5%, p = 0.007) increase in target error. Bilateral lead placement was associated with 26.0% (95% CI: 9.9-44.5%, p = 0.002) longer lead placement time. The relationship between placement time and lead sequence number was nonlinear: it decreased consistently for the first 4 electrodes, and became less pronounced thereafter.

Conclusions: Variation in sEEG electrode placement efficiency and accuracy can be explained by phenomena both within and outside of operator control. It is important to keep in mind the factors that can lead to better or worse lead placement efficiency and/or accuracy in order to maximize patient safety while maintaining the standard of care.

Citing Articles

Clinical Applicability and Safety of Conventional Frame-Based Stereotactic Techniques for Stereoelectroencephalography.

Kim J, Hong S, Kim H, Yum M, Ko T, Koo Y J Korean Neurosurg Soc. 2024; 67(6):661-674.

PMID: 38986517 PMC: 11540521. DOI: 10.3340/jkns.2023.0246.

Usefulness of Robotic Stereotactic Assistance (ROSA) Device for Stereoelectroencephalography Electrode Implantation: A Systematic Review and Meta-analysis.

Kaewborisutsakul A, Chernov M, Yokosako S, Kubota Y Neurol Med Chir (Tokyo). 2024; 64(2):71-86.

PMID: 38220166 PMC: 10918457. DOI: 10.2176/jns-nmc.2023-0119.

Robotic-Assisted Stereoelectroencephalography: A Systematic Review and Meta-Analysis of Safety, Outcomes, and Precision in Refractory Epilepsy Patients.

Vasconcellos F, Almeida T, Fiedler A, Fountain H, Piedade G, Monaco B Cureus. 2023; 15(10):e47675.

PMID: 38021558 PMC: 10672406. DOI: 10.7759/cureus.47675.

Stereoelectroencephalography in the very young: Case report.

Katz J, Armstrong C, Kvint S, Kennedy B Epilepsy Behav Rep. 2022; 19:100552.

PMID: 35664664 PMC: 9157455. DOI: 10.1016/j.ebr.2022.100552.

FreeSurfer and 3D Slicer-Assisted SEEG Implantation for Drug-Resistant Epilepsy.

Liu Q, Wang J, Wang C, Wei F, Zhang C, Wei H Front Neurorobot. 2022; 16:848746.

PMID: 35295674 PMC: 8918516. DOI: 10.3389/fnbot.2022.848746.

References

De Benedictis A, Trezza A, Carai A, Genovese E, Procaccini E, Messina R . Robot-assisted procedures in pediatric neurosurgery. Neurosurg Focus. 2017; 42(5):E7. DOI: 10.3171/2017.2.FOCUS16579. View

Carai A, Mastronuzzi A, De Benedictis A, Messina R, Cacchione A, Miele E . Robot-Assisted Stereotactic Biopsy of Diffuse Intrinsic Pontine Glioma: A Single-Center Experience. World Neurosurg. 2017; 101:584-588. DOI: 10.1016/j.wneu.2017.02.088. View

Lefranc M, Capel C, Pruvot-Occean A, Fichten A, Desenclos C, Toussaint P . Frameless robotic stereotactic biopsies: a consecutive series of 100 cases. J Neurosurg. 2014; 122(2):342-52. DOI: 10.3171/2014.9.JNS14107. View

Miller B, Salehi A, Limbrick Jr D, Smyth M . Applications of a robotic stereotactic arm for pediatric epilepsy and neurooncology surgery. J Neurosurg Pediatr. 2017; 20(4):364-370. DOI: 10.3171/2017.5.PEDS1782. View

Parvizi J, Kastner S . Promises and limitations of human intracranial electroencephalography. Nat Neurosci. 2018; 21(4):474-483. PMC: 6476542. DOI: 10.1038/s41593-018-0108-2. View

Alomar S, Mullin J, Smithason S, Gonzalez-Martinez J . Indications, technique, and safety profile of insular stereoelectroencephalography electrode implantation in medically intractable epilepsy. J Neurosurg. 2017; 128(4):1147-1157. DOI: 10.3171/2017.1.JNS161070. View

Gonzalez-Martinez J, Bulacio J, Alexopoulos A, Jehi L, Bingaman W, Najm I . Stereoelectroencephalography in the "difficult to localize" refractory focal epilepsy: early experience from a North American epilepsy center. Epilepsia. 2012; 54(2):323-30. DOI: 10.1111/j.1528-1167.2012.03672.x. View

Kim L, Parker J, Ho A, Pendharkar A, Sussman E, Halpern C . Postoperative outcomes following pediatric intracranial electrode monitoring: A case for stereoelectroencephalography (SEEG). Epilepsy Behav. 2020; 104(Pt A):106905. DOI: 10.1016/j.yebeh.2020.106905. View

Kovac S, Vakharia V, Scott C, Diehl B . Invasive epilepsy surgery evaluation. Seizure. 2016; 44:125-136. DOI: 10.1016/j.seizure.2016.10.016. View

10.

Minotti L, Montavont A, Scholly J, Tyvaert L, Taussig D . Indications and limits of stereoelectroencephalography (SEEG). Neurophysiol Clin. 2018; 48(1):15-24. DOI: 10.1016/j.neucli.2017.11.006. View

11.

Mullin J, Sexton D, Al-Omar S, Bingaman W, Gonzalez-Martinez J . Outcomes of Subdural Grid Electrode Monitoring in the Stereoelectroencephalography Era. World Neurosurg. 2016; 89:255-8. DOI: 10.1016/j.wneu.2016.02.034. View

12.

Yan H, Katz J, Anderson M, Mansouri A, Remick M, Ibrahim G . Method of invasive monitoring in epilepsy surgery and seizure freedom and morbidity: A systematic review. Epilepsia. 2019; 60(9):1960-1972. DOI: 10.1111/epi.16315. View