Your search keyword '"sEEG"' showing total 1,039 results

1. Enhancing epilepsy care in Argentina: Use of SEEG in a developing setting

Author

Oddo, Silvia, Giagante, Brenda, Seoane, Eduardo, Seoane, Pablo, Princich, Juan P, Campora, Nuria, Nasimbera, Alejandro, and Kochen, Silvia

Published

2025

2. Seizure outcome in drug-resistant epilepsy in the setting of polymicrogyria

Author

Aung, Thandar, Bo, Jin, Bingaman, William, Najm, Imad, Alexopoulos, Andreas, and Bulacio, Juan C.

Published

2024

3. The involvement of the piriform cortex in non-lesional temporal lobe epilepsy: an uncommon component of the epileptogenic network

Author

Pedersen, Nigel P, Raghu, Ashley, Shivamurthy, Veeresh Kumar N, Chern, Joshua J, Gross, Robert E, Willie, Jon T, Dingledine, Raymond J, and Kheder, Ammar

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Clinical Research, Neurodegenerative, Epilepsy, Brain Disorders, 2.1 Biological and endogenous factors, Neurological, piriform cortex, temporal lobe epilepsy, stereo-electroencephalography, SEEG, olfactory aura, Clinical sciences, Biological psychology

Abstract

The piriform cortex is recognized as highly epileptogenic in rodents, yet its electrophysiological role in human epilepsy remains understudied. Recent surgical outcomes have suggested potential benefits in resecting the piriform cortex for cases of medial temporal lobe epilepsy. However, little is known about its electrophysiological activity in human epilepsy. This case-series study aimed to explore the electrophysiological role of the piriform cortex within the epileptogenic network among patients with suspected temporal lobe epilepsy. Participants were recruited from Emory University Hospital or Children's Healthcare of Atlanta, with non-lesional frontotemporal or temporal lobe hypotheses, undergoing stereoelectroencephalographic studies. Specifically, focus was placed on patients with one or more electrode contacts in the piriform cortex. Primary objectives included determining piriform cortex involvement within the electrophysiologically defined epileptogenic network and assessing the effects of electrical stimulation. Twenty-two patients were included in the study. Notably, only one patient exhibited piriform cortex involvement at seizure onset, associated with an olfactory aura. Two patients showed early piriform cortex involvement, while others displayed late or no involvement. Electrical stimulation of the piriform cortex induced after-discharges in three patients and replicated a habitual seizure in one. These findings present a contrast to surgical outcome studies, suggesting that the piriform cortex may not typically play a significant role in the epileptogenic network among patients with non-lesional temporal lobe epilepsy.

Published

2024

4. Stereoelectroencephalography (SEEG)-guided insula resections: is it “Reily” worth it?

Author

Pepper, J., Seri, S., Walsh, A. R., Agrawal, S., Macpherson, L., Sudarsanam, A., and Lo, W. B.

Abstract

Objective: Stereoelectroencephalography (SEEG) is widely used to characterise epileptic networks and guide resection in paediatric epilepsy surgery programmes. The insula, with its extensive connectivity with temporal and extratemporal structures, has increasingly been seen as a possible surgical target. We report our seizure outcomes after SEEG-guided resection of the insula in a paediatric cohort. Methods: From our paediatric epilepsy surgery database of patients aged 0–19 years, we analysed demographic and clinical data of those who underwent SEEG-guided insula cortex resection. Results: In total, 11 children (7 females, 4 males) who underwent SEEG-guided resection were identified. The mean age at first SEEG was 13 years old. Mean age at seizure onset was 4.3 years; seizure frequency ranged from 50/day to 2/week. Four children required 1 SEEG study, 6 children 2 SEEG, and 1 child underwent 3 SEEG recordings. The mean follow-up duration was 2.1 years; at the latest follow-up, three children had Engel I, 2 children Engel III, and 6 children Engel IV. One child classified as an Engel IV outcome for insular surgery had Engel class I after 2 failed insula surgeries, after an occult frontal focal cortical dysplasia was later identified and resected. No major complications were noted. Conclusions: In our paediatric series, one third of the patients undergoing insula cortex surgery after SEEG became seizure free but this may require repeat SEEG implantation, repeat resective surgery and the possibility of changing hypothesis from the insula cortex to nearby foci. [ABSTRACT FROM AUTHOR]

Published

2025

5. Trends and hotspots of stereoelectroencephalogram from 2002 to 2023: a bibliometric analysis.

Author

Wang, Tianren, Dong, Hengxin, Li, Kaiwei, Feng, Tao, Yang, Yanfeng, Chen, Sichang, Lu, Di, Wei, Penghu, Shan, Yongzhi, and Zhao, Guoguang

Subjects

BIBLIOMETRICS, EPILEPSY, STEREOTAXIC techniques, COMPUTER science, CHINA-United States relations

Abstract

Background: Stereoelectroencephalography (SEEG), as a minimally invasive method that can stably collect intracranial electroencephalographic information over long periods, has increasingly been applied in the diagnosis and treatment of intractable epilepsy in recent years. Over the past 20 years, with the advancement of materials science and computer science, the application scenarios of SEEG have greatly expanded. Bibliometrics, as a method of scientifically analyzing published literature, can summarize the evolutionary process in the SEEG field and offer insights into its future development prospects. Methods: This article selected all the literature records retrieved on November 4, 2024, from the Web of Science Core Collection (WoSCC). The search terms were as follows: "Stereo-electroencephalography" or "Stereo electroencephalography" or "Stereo-EEG" or "Stereo EEG" or "SEEG." The document types included were research articles and reviews. For analysis, VOSviewer, CiteSpace, and the R package "bibliometrix" were employed to analyze various aspects of the SEEG field, including authors, institutions, countries and regions, and research hotspots. Results: We reviewed a total of 1,383 non-duplicate literature records from 2002 to 2023, including 1,241 research articles, 116 review articles and 26 letters. Observing the annual publication trends, there has been an overall increase since 2002. The most influential journal in this field is Epilepsia. Other journals with considerable impact include Clinical Neurophysiology , Epileptic Disorders , Epilepsy Research , NeuroImage , and Epilepsy & Behavior. The top 5 most influential scholars are Bartolomei F, Tassi L, Nobili L, Russo GL, and Mc Gonigal A. As for the analysis of countries and regions, France occupies a leading position in this field with its early start, while China and the United States have also emerged as focal points since 2020. Research on SEEG has expanded beyond its initial use for localizing epileptic foci and thermo-coagulation treatments and have been employed as a medium to facilitate real-time prediction of epileptic seizures and enabling the exploration of brain network connectivity. Conclusion: As a minimally invasive tool for collecting intracranial electroencephalographic signals, SEEG continues to offer vast potential for development and application. Advances in electrode materials and robotic-assisted stereotactic techniques, have enabled SEEG to simultaneously sample multiple brain regions, acquire electrical signals from deep brain structures. These advantages significantly enhance the precision of epileptic focus localization in diagnosis and treatment, addressing the limitations of subdural electrodes. Through bibliometric analysis, this paper traces the developmental trajectory of SEEG and identifying key technological milestones, thereby providing a reference for scholarly research directions. [ABSTRACT FROM AUTHOR]

Published

2024

6. Insular Epilepsy: Functions, Diagnostic Approaches, and Surgical Interventions.

Author

Ekman, Felix R. and González-Martínez, Jorge A.

Subjects

*NEUROLOGICAL disorders, *SURGICAL excision, *EPILEPSY, *ELECTROCOAGULATION (Medicine), *SEIZURES (Medicine)

Abstract

Epilepsy, a chronic neurological disorder characterized by recurrent seizures, affects a significant portion of the global population, with drug-resistant epilepsy (DRE) presenting a major treatment challenge. Insular epilepsy, originating from this complex region, exhibits a broad range of symptoms, making diagnosis particularly difficult. Advanced imaging techniques and invasive procedures like stereoelectroencephalography (SEEG) are often crucial for accurately localizing the epileptogenic zone. Surgical resection remains the primary treatment for DRE, with recent advancements in microsurgical techniques and neuroimaging improving outcomes. Additionally, minimally invasive approaches like laser interstitial thermal therapy (LITT) and radiofrequency thermocoagulation (RFTC) offer promising alternatives. [ABSTRACT FROM AUTHOR]

Published

2024

7. Accuracy of frameless robot-assisted stereoelectroencephalography depth electrode implantation using the neurolocate registration system in paediatric patients.

Author

Kurzbuch, Arthur R., Scala, Maria R., Cooper, Ben, Kitchen, John, Tronnier, Volker, and Ellenbogen, Jonathan

Subjects

*CHILD patients, *CHILDREN with epilepsy, *CHILDHOOD epilepsy, *ELECTRODES, *EPILEPSY

Abstract

AbstractBackgroundMethodsResultsConclusionWe assessed the accuracy and performed a directional analysis of robot-assisted implantation of stereoelectroencephalography (SEEG) depth electrodes in children using the frameless neurolocate 3D registration module.Thirteen children with epilepsy undergoing stereotactic robot-assisted insertion of SEEG electrodes were included. Six children were operated on with standard frame-based registration while 7 with the use of the frameless neurolocate registration module. Accuracy and directional analysis of orthogonal and oblique electrodes were assessed by calculating the absolute error, the radial error, the angle error, and the Euclidean distance.Of 172 electrodes 89 were implanted in the 6 standard frame-based mode patients and 83 in the 7 neurolocate patients. The overall mean age was 12.2 ± 4.4 years (range 2–17). The mean number of electrodes in each patient was 13.2 ± 2.04 (range 9–17). The median radial error of electrode placement in the neurolocate patients (1.08 mm, [IQR: 1.26]) was significantly less when compared with standard frame-based mode patients (1.49 mm, [IQR 1.25)]; p = 0.04). The same applies to the median angle error which was in the neurolocate group 1.61° [IQR: 1.46] and in the standard frame-based group 2.16° [IQR: 2.09]; p = 0.019. Directional analysis of electrode trajectories in the neurolocate group showed that in the x-axis the median absolute error of orthogonal electrodes (0.4 mm, [IQR: 0.475]) was less when compared with oblique electrodes (0.7 mm, [IQR: 1.2]; p = 0.007). In the standard frame-based mode group in the y-axis, the median absolute error of orthogonal electrodes (0.7 mm, [IQR: 1.3]) was less compared with oblique electrodes (1.25 mm, [IQR: 1.6]; p = 0.03).In paediatric patients, robot-assisted SEEG depth electrode implantation with the non-invasive and easy-to-use frameless neurolocate registration module is a consistent and accurate procedure. [ABSTRACT FROM AUTHOR]

Published

2024

8. Epilepsy surgery in children with operculoinsular epilepsy: Results of a large unicentric cohort.

Author

Kudr, Martin, Janca, Radek, Jahodova, Alena, Belohlavkova, Anezka, Ebel, Matyas, Bukacova, Katerina, Maulisova, Alice, Tichy, Michal, Liby, Petr, Kyncl, Martin, Holubova, Zuzana, Sanda, Jan, Jezdik, Petr, Mackova, Katerina, Ramos Rivera, Gonzalo Alonso, Kopac, Luka, and Krsek, Pavel

Subjects

*TUBEROUS sclerosis, *CHILD patients, *CHILDREN with epilepsy, *EPILEPSY surgery, *MAGNETIC resonance imaging, *TEMPORAL lobectomy

Abstract

Objective Methods Results Significance Epilepsy surgery in the operculoinsular cortex is challenging due to the difficult delineation of the epileptogenic zone and the high risk of postoperative deficits.Pre‐ and postsurgical data from 30 pediatric patients who underwent operculoinsular cortex surgery at the Motol Epilepsy Center Prague from 2010 to 2022 were analyzed.Focal cortical dysplasia (FCD; n = 15, 50%) was the predominant cause of epilepsy, followed by epilepsy‐associated tumors (n = 5, 17%) and tuberous sclerosis complex (n = 2, 7%). In eight patients where FCD was the most likely etiology, the histology was negative. Seven patients (23%) displayed normal magnetic resonance imaging results. Seizures exhibited diverse semiology and propagation patterns (frontal, perisylvian, and temporal). The ictal and interictal electroencephalographic (EEG) findings were mostly extensive. Multimodal imaging and advanced postprocessing were frequently used. Stereo‐EEG was used for localizing the epileptogenic zone and eloquent cortex in 23 patients (77%). Oblique electrodes were used as guides for better neurosurgeon orientation. The epileptogenic zone was in the dominant hemisphere in 16 patients. At the 2‐year follow‐up, 22 patients (73%) were completely seizure‐free, and eight (27%) experienced a seizure frequency reduction of >50% (International League Against Epilepsy class 3 and 4). Fourteen patients (47%) underwent antiseizure medication tapering; treatment was completely withdrawn in two (7%). Nineteen patients (63%) remained seizure‐free following the definitive outcome assessment (median = 6 years 5 months, range = 2 years to 13 years 5 months postsurgery). Six patients (20%) experienced corona radiata or basal ganglia ischemia; four (13%) improved to mild and one (3%) to moderate hemiparesis. Two patients (7%) operated on in the anterior insula along with frontotemporal resection experienced major complications: pontine ischemia and postoperative brain edema.Epilepsy surgery in the operculoinsular cortex can lead to excellent patient outcomes. A comprehensive diagnostic approach is crucial for surgical success. Rehabilitation brings a great chance for significant recovery of postoperative deficits. [ABSTRACT FROM AUTHOR]

Published

2024

9. Patterns of ictal surface EEG in occipital seizures: A simultaneous scalp and intracerebral recording study.

Author

Cheval, Margaux, Ferrand, Mickaël, Colnat-Coubois, Sophie, Aron, Olivier, Tyvaert, Louise, Koessler, Laurent, and Maillard, Louis

Subjects

*EPILEPSY surgery, *SCALP, *ELECTROENCEPHALOGRAPHY, *SEIZURES (Medicine), *MEDICAL personnel, *ELECTRONOGRAPHY

Abstract

• Scalp EEG accurately determines intra-cerebral seizure onset time in occipital seizures. • Scalp EEG has good lateralizing value (71 %). • Initial scalp EEG modification does not always involves occipital electrodes (50 %). To describe the ictal scalp EEG patterns of occipital seizures (OS) and their spatiotemporal correlations with intracerebral occipital ictal discharges derived from simultaneous SEEG-EEG recordings. Patients with SEEG confirmed OS (14 OS from 8 patients) were selected from an epilepsy surgery center and were monitored 3–10 days using simultaneous scalp EEG and SEEG recordings. On scalp EEG, the most common onset patterns were background activity suppression (28.6 %) and high amplitude slow wave corresponding to intracerebral DC-shift (28.6 %) and occurred with a median delay of 0 s after intra-cerebral onset. The initial discharge involved occipital electrodes in only 50 % of the seizures (7/14) with additional basal temporal (8/14) or parietal electrodes (5/14). The onset was ipsilateral to the intra-cerebral onset zone in 71.4 % of seizures and bilateral in the remaining (28.6 %). The most common propagation pattern was either unilateral (50 %) or bilateral (50 %) and a rhythmic slow activity (66.7 %). Different OS subtypes display distinct scalp EEG patterns. Scalp EEG accurately determines intra-cerebral seizure onset time in OS and has good lateralizing value. However, initial scalp modification does not always involves occipital electrodes and the second modification is well lateralizing in only 50 % of seizures. This study describes will help clinicians to better identify OS during video EEG and better plan intra-cerebral explorations for epilepsy surgery. [ABSTRACT FROM AUTHOR]

Published

2024

10. 高频脑磁分析在立体定向脑电图射频热凝治疗 药物难治性癫痫中的应用.

Author

付东翔, 吴杰, 谭家亮, 谷宇, 陈月明, and 陆东生

Abstract

Objective To explore the application and efficacy of high-frequency brain magnetic field analysis in stereo-electroencephalography (SEEG) radiofrequency thermal coagulation treatment for drug-resistant epilepsy. Methods The data of 11 patients with drug-resistant epilepsy who were admitted to the sixth ward, Department of Neurosurgery, Sanjiu Brain Hospital of Guangdong Province, from January 2022 to December 2022 were analyzed retrospectively. CURRY8 software was utilized for fusion analysis and evaluation of various imaging and electrophysiological data to locate possible epileptogenic foci and develop a plan for SEEG electrode implantation and parallel deep brain electrode implantation was performed. Postoperative SEEG was performed to monitor and observe the patients' EEG changes during the seizure period, combined with the preoperative images and SEEG data. Deep brain electrode epileptic foci destruction was performed according to the analyzed results, and the surgical efficacy was evaluated by regular postoperative follow-up for 3-6 months. Results Eleven patients underwent deep brain electrode radiofrequency thermocoagulation disruption based on the seizure initiation sites observed by SEEG. The efficacy of postoperative follow- up was Engel grade I in 6 patients, grade II in 3, grade III in 1, and grade IV in 1. Conclusions High-frequency magnetoencephalography analysis is both safe and reliable, providing a more precise foundation for the localization of epileptogenic zones. When combined with multimodal fusion analysis and comprehensive evaluation of various imaging techniques and electrophysiology, it enables a more intuitive and accurate identification of epileptogenic zones while optimizing the SEEG implantation plan. This approach ensures maximum surgical efficacy with minimal trauma, thereby offering significant benefits to patients suffering from drug-resistant epilepsy [ABSTRACT FROM AUTHOR]

Published

2024

11. Exploration of epileptic networks in temporal lobe encephaloceles with stereotactic EEG: Electroclinical characteristics and surgical outcomes.

Author

Zillgitt, Andrew J., Mong, Eric R., Manasseh, Angelique M., Guider, Hannah C., Baki, Nour, and Staudt, Michael D.

Subjects

TEMPORAL lobe epilepsy, TEMPORAL lobe, EPILEPTIFORM discharges, EPILEPSY surgery, TIME-varying networks

Abstract

Objective: Temporal lobe encephaloceles (TLEN) have been implicated as a cause of temporal lobe epilepsy (TLE), the treatment which is primarily surgical; however, there is no clear consensus on the optimal surgical approach, because it is unclear whether TLE related to TLEN can be addressed by a restricted encephalocele resection or if a more extensive resection is required. The aim of the current article is to report the clinical and electrophysiological profile of patients with TLE secondary to TLEN who underwent stereotactic electroencephalography (SEEG) implantation to identify the epileptogenic network. Methods: A retrospective review was performed of patients with TLE related to TLEN who underwent SEEG implantation. Medical charts were reviewed for demographic data, the results of noninvasive and invasive investigations, and operative details. Surgical outcomes were based on Engel classification with at least 6 months follow‐up. Results: Nine patients were identified. The mean age at epilepsy onset was 28 years (range, 15–41 years), and 7/9 patients were female. Scalp EEG revealed interictal epileptiform activity most often maximum in the frontotemporal and/or temporal regions. A discrete TLEN was often not identified on initial imaging, but was identified during re‐review or at the time of surgery. Seizure onset zones during SEEG were localized to the mesial temporal structures, the temporal pole, or both. One patient became seizure‐free following SEEG and another refused further surgery. Of the 7 patients who underwent epilepsy surgery, 5/7 underwent an anterior temporal lobectomy—surgical outcomes were favorable, with 5/7 achieving Engel I outcomes. Significance: Invasive SEEG monitoring demonstrated ictal onsets may not be restricted to the TLEN, and often the temporal pole and mesial structures are involved at seizure onset. Ictal propagation patterns vary significantly, which may be related to the underlying pathology and explain the variability in semiology. These findings may inform surgical treatment options. Plain language summary: Temporal lobe encephaloceles can cause intractable epilepsy, although their presence may be missed on routine imaging. The management of encephaloceles is primarily surgical; however, the optimal surgical approach can be unclear. Invasive monitoring with SEEG may help characterize the epileptogenic network and result in more optimal surgical outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

12. Exploration of epileptic networks in temporal lobe encephaloceles with stereotactic EEG: Electroclinical characteristics and surgical outcomes

Author

Andrew J. Zillgitt, Eric R. Mong, Angelique M. Manasseh, Hannah C. Guider, Nour Baki, and Michael D. Staudt

Subjects

case series, encephalocele, epilepsy, epileptogenic network, SEEG, temporal lobe, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Objective Temporal lobe encephaloceles (TLEN) have been implicated as a cause of temporal lobe epilepsy (TLE), the treatment which is primarily surgical; however, there is no clear consensus on the optimal surgical approach, because it is unclear whether TLE related to TLEN can be addressed by a restricted encephalocele resection or if a more extensive resection is required. The aim of the current article is to report the clinical and electrophysiological profile of patients with TLE secondary to TLEN who underwent stereotactic electroencephalography (SEEG) implantation to identify the epileptogenic network. Methods A retrospective review was performed of patients with TLE related to TLEN who underwent SEEG implantation. Medical charts were reviewed for demographic data, the results of noninvasive and invasive investigations, and operative details. Surgical outcomes were based on Engel classification with at least 6 months follow‐up. Results Nine patients were identified. The mean age at epilepsy onset was 28 years (range, 15–41 years), and 7/9 patients were female. Scalp EEG revealed interictal epileptiform activity most often maximum in the frontotemporal and/or temporal regions. A discrete TLEN was often not identified on initial imaging, but was identified during re‐review or at the time of surgery. Seizure onset zones during SEEG were localized to the mesial temporal structures, the temporal pole, or both. One patient became seizure‐free following SEEG and another refused further surgery. Of the 7 patients who underwent epilepsy surgery, 5/7 underwent an anterior temporal lobectomy—surgical outcomes were favorable, with 5/7 achieving Engel I outcomes. Significance Invasive SEEG monitoring demonstrated ictal onsets may not be restricted to the TLEN, and often the temporal pole and mesial structures are involved at seizure onset. Ictal propagation patterns vary significantly, which may be related to the underlying pathology and explain the variability in semiology. These findings may inform surgical treatment options. Plain language summary Temporal lobe encephaloceles can cause intractable epilepsy, although their presence may be missed on routine imaging. The management of encephaloceles is primarily surgical; however, the optimal surgical approach can be unclear. Invasive monitoring with SEEG may help characterize the epileptogenic network and result in more optimal surgical outcomes.

Published

2024

13. Understanding the human conflict processing network: A review of the literature on direct neural recordings during performance of a modified stroop task

Author

Ryan S. Chung, Jonathon Cavaleri, Shivani Sundaram, Zachary D. Gilbert, Roberto Martin Del Campo-Vera, Andrea Leonor, Austin M. Tang, Kuang-Hsuan Chen, Rinu Sebastian, Arthur Shao, Alexandra Kammen, Emiliano Tabarsi, Angad S. Gogia, Xenos Mason, Christi Heck, Charles Y. Liu, Spencer S. Kellis, and Brian Lee

Subjects

Stroop task, Conflict processing, SEEG, Epilepsy, Beta, Theta, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The Stroop Task is a well-known neuropsychological task developed to investigate conflict processing in the human brain. Our group has utilized direct intracranial neural recordings in various brain regions during performance of a modified color-word Stroop Task to gain a mechanistic understanding of non-emotional human conflict processing. The purpose of this review article is to: 1) synthesize our own studies into a model of human conflict processing, 2) review the current literature on the Stroop Task and other conflict tasks to put our research in context, and 3) describe how these studies define a network in conflict processing. The figures presented are reprinted from our prior publications and key publications referenced in the manuscript. We summarize all studies to date that employ invasive intracranial recordings in humans during performance of conflict-inducing tasks. For our own studies, we analyzed local field potentials (LFPs) from patients with implanted stereotactic electroencephalography (SEEG) electrodes, and we observed intracortical oscillation patterns as well as intercortical temporal relationships in the hippocampus, amygdala, and orbitofrontal cortex (OFC) during the cue-processing phase of a modified Stroop Task. Our findings suggest that non-emotional human conflict processing involves modulation across multiple frequency bands within and between brain structures.

Published

2024

14. Spatiotemporal Neural Network for Sublexical Information Processing: An Intracranial SEEG Study.

Author

Chunyu Zhao, Yi Liu, Jiahong Zeng, Xiangqi Luo, Weijin Sun, Guoming Luan, Yuxin Liu, Yumei Zhang, Gaofeng Shi, Yuguang Guan, and Zaizhu Han

Subjects

*PREFRONTAL cortex, *INFORMATION networks, *INFORMATION processing, *RECOGNITION (Psychology), *TEMPORAL lobe, *FUSIFORM gyrus

Abstract

Words offer a unique opportunity to separate the processing mechanisms of object subcomponents from those of the whole object, because the phonological or semantic information provided by the word subcomponents (i.e., sublexical information) can conflict with that provided by the whole word (i.e., lexical information). Previous studies have revealed some of the specific brain regions and temporal information involved in sublexical information processing. However, a comprehensive spatiotemporal neural network for sublexical processing remains to be fully elucidated due to the low temporal or spatial resolutions of previous neuroimaging studies. In this study, we recorded stereoelectroencephalography signals with high spatial and temporal resolutions from a large sample of 39 epilepsy patients (both sexes) during a Chinese character oral reading task. We explored the activated brain regions and their connectivity related to three sublexical effects: phonological regularity (whether the whole character's pronunciation aligns with its phonetic radical), phonological consistency (whether characters with the same phonetic radical share the same pronunciation), and semantic transparency (whether the whole character's meaning aligns with its semantic radical). The results revealed that sublexical effects existed in the inferior frontal gyrus, precentral and postcentral gyri, temporal lobe, and middle occipital gyrus. Additionally, connectivity from the middle occipital gyrus to the postcentral gyrus and from postcentral gyrus to the fusiform gyrus was associated with the sublexical effects. These findings provide valuable insights into the spatiotemporal dynamics of sublexical processing and object recognition in the brain. [ABSTRACT FROM AUTHOR]

Published

2024

15. Optimizing outcomes in drug-resistant mesial temporal lobe epilepsy patients undergoing stereoelectroencephalography-guided radiofrequency thermocoagulation.

Author

Jean, Stéphane, Jiang, Rifeng, Dai, Yihai, Chen, Weitao, Liu, Weihong, Deng, Donghuo, Tagu, Panashe Tevin, Wei, Xiaoqiang, Chen, Shan, Fang, Xinrong, and Song, Shiwei

Subjects

TEMPORAL lobe epilepsy, GRAY matter (Nerve tissue), WHITE matter (Nerve tissue), TEMPORAL lobe, EPILEPTIFORM discharges, BODY surface mapping, VOXEL-based morphometry

Abstract

Background: Mesial temporal lobe epilepsy (MTLE) epileptiform discharges have been reported to arise from the hippocampus or the extrahippocampal medial temporal cortex, such as the amygdala, and then propagate to the temporal lobe cortex. The surgical ablation of which of these structures would result in a better postoperative outcome is debatable. Objective: To assess the possible factors that might have influenced the postoperative outcome of a group of drug-resistant mesial MTLE patients who underwent stereoelectroencephalography (SEEG)-guided radiofrequency thermocoagulation (RFTC). Design: Single-center, retrospective. Methods: The present study utilized a pre- and postoperative gray matter voxel-by-voxel ablation mapping comparison approach, along with a white matter mapping of longitudinal changes in the native space technique, to evaluate the association between the post-SEEG implantation signal recordings (obtained from clinically relevant electrode contacts used during RFTC) and the post-RFTC ablation volume of the different selected regions of interest (ROIs). Results: The study included 22 patients (12 men and 10 women, mean age 28.86 ± 14.04 years). Sixteen patients (72.72%) were seizure-free (SF), and six patients (27.27%) were non-SF. Five patients (22.72%) experienced mild side effects following RFTC. The post-RFTC follow-up period varied from 12 to 48 months, with an average of 24.17 ± 9.86 months. The SF group was associated with a higher number of implanted electrode contacts in the amygdala that were used during RFTC, a larger preoperative volume of the amygdala; a larger ablation volume of both the amygdala and rhinal cortex. The ablation volume of the white matter was statistically similar between both groups. Conclusion: This study provides valuable insights into the significance of the amygdala and rhinal cortex as ROIs in the preoperative evaluation of patients with MTLE. Future implantation scheme plans should consider evaluating the preoperative volume of these ROIs. Additionally, increasing the number of electrode contacts implanted within these regions might be beneficial to capture more clinically relevant signals and enhance their ablation volume. [ABSTRACT FROM AUTHOR]

Published

2024

16. Impact of transcranial electrical stimulation on simultaneous stereoelectroencephalography recordings: A randomized sham-controlled study.

Author

Simula, Sara, Makhalova, Julia, Pizzo, Francesca, Garnier, Elodie, Damiani, Giada, Mercadal, Borja, Chiara Biagi, Maria, Salvador, Ricardo, Medina-Villalon, Samuel, Ruffini, Giulio, Wendling, Fabrice, George Bénar, Christian, and Bartolomei, Fabrice

Subjects

*ELECTRIC stimulation, *PARTIAL epilepsy, *EPILEPTIFORM discharges, *ALTERNATING currents, *FUNCTIONAL connectivity

Abstract

• This is the first study to examine tES (transcranial electrical stimulation) effects using simultaneous intracranial recordings. • We quantify local and network changes during and closely following application of direct and alternating current stimulation. • Highlighting the variability in tES physiological effects, our findings underscore the importance of sham in clinical studies. Clinical exploitation of transcranial electrical stimulation for focal epilepsy treatment lacks quantification of the underlying neurophysiological changes. This study explores the immediate effects of transcranial alternating (tACS) and direct (tDCS) current stimulation on local and network brain activity using simultaneous stereoelectroencephalography (SEEG) recordings. Patients were randomized for personalized tACS (n = 5) or tDCS (n = 6). Active stimulation (20 min) was preceded by sham stimulation (20 min). Changes in interictal epileptiform discharges (IED), functional connectivity (FC) and power spectral density (PSD) were quantified against baseline. Results demonstrated variable responses. Spike rate decreased in 2/6 subjects following sham and tDCS, while 2/6 showed an increase. Alpha power and aperiodic PSD components generally increased during and after tDCS but decreased following tACS. FC changes varied among subjects and were detectable even during sham sessions. Strong variability suggests that tES does not have a univocal effect on immediate changes in IED or FC, possibly due to the single session format and challenges in affecting subcortical areas. This is the first study to examine intracranial FC changes during tACS and tDCS, highlighting the importance of sham comparisons and individual variability in tES response, offering valuable insights into its application for epilepsy treatment. [ABSTRACT FROM AUTHOR]

Published

2024

17. SEEG4D: a tool for 4D visualization of stereoelectroencephalography data.

Author

Evans, James L., Bramlet, Matthew T., Davey, Connor, Bethke, Eliot, Anderson, Aaron T., Huesmann, Graham, Varatharajah, Yogatheesan, Maldonado, Andres, Amos, Jennifer R., and Sutton, Bradley P.

Subjects

MAGNETIC resonance imaging, SPATIAL ability, NEUROLOGICAL disorders, COMPUTED tomography, VIRTUAL reality

Abstract

Epilepsy is a prevalent and serious neurological condition which impacts millions of people worldwide. Stereoelectroencephalography (sEEG) is used in cases of drug resistant epilepsy to aid in surgical resection planning due to its high spatial resolution and ability to visualize seizure onset zones. For accurate localization of the seizure focus, sEEG studies combine pre-implantation magnetic resonance imaging, post-implant computed tomography to visualize electrodes, and temporally recorded sEEG electrophysiological data. Many tools exist to assist in merging multimodal spatial information; however, few allow for an integrated spatiotemporal view of the electrical activity. In the current work, we present SEEG4D, an automated tool to merge spatial and temporal data into a complete, four-dimensional virtual reality (VR) object with temporal electrophysiology that enables the simultaneous viewing of anatomy and seizure activity for seizure localization and presurgical planning. We developed an automated, containerized pipeline to segment tissues and electrode contacts. Contacts are aligned with electrical activity and then animated based on relative power. SEEG4D generates models which can be loaded into VR platforms for viewing and planning with the surgical team. Automated contact segmentation locations are within 1 mm of trained raters and models generated show signal propagation along electrodes. Critically, spatial-temporal information communicated through our models in a VR space have potential to enhance sEEG pre-surgical planning. [ABSTRACT FROM AUTHOR]

Published

2024

18. An Unusual Case of Hypothalamic Hamartoma With Nongelastic Seizures and Posterior Cortex Connectivity.

Author

Al-Ramadhani, Ruba, Bhalla, Sonam, Bearden, Donald J., Ono, Kimi, Chern, Joshua, and Kheder, Ammar

Subjects

*LASER ablation, *TIME-varying networks, *SEIZURES (Medicine), *HAMARTOMA, *AGE of onset, *PEOPLE with epilepsy

Abstract

To describe a rare seizure semiology originating from a hypothalamic hamartoma in a child, along with unusual ictal onset and connectivity pattern, and provide a review of the pathophysiology of epilepsy associated with hypothalamic hamartoma and management. A detailed retrospective chart review and literature search were performed using Pubmed and Embase. We present a case of a three-year-old male who presented with dyscognitive seizures with onset at age 22 months. Stereoelectroencephalography exploration confirmed the onset in hypothalamic hamartoma with rapid propagation to the temporal-parietal-occipital association cortex and precuneus. The patient's epilepsy was cured with laser ablation of the hamartoma. Published literature mostly describes a more anterior frontal or temporal epileptic network with primarily gelastic seizures being the hallmark type of seizures associated with hypothalamic hamartoma. We highlight a rare posterior cortex network with an atypical presentation of focal nonmotor seizures with impaired awareness in the setting of a hypothalamic hamartoma. Stereotactic laser ablation of the hamartoma rendered seizure freedom. Early diagnosis and appropriate treatment can lead to seizure freedom. [ABSTRACT FROM AUTHOR]

Published

2024

19. Bidirectional and Cross-Hemispheric Modulations of Face-Selective Neural Activity Induced by Electrical Stimulation within the Human Cortical Face Network.

Author

Angelini, Luna, Jacques, Corentin, Maillard, Louis, Colnat-Coulbois, Sophie, Rossion, Bruno, and Jonas, Jacques

Subjects

*ELECTRIC stimulation, *FUNCTIONAL connectivity, *BRAIN stimulation, *COGNITIVE neuroscience, *TEMPORAL lobe

Abstract

A major scientific objective of cognitive neuroscience is to define cortico-cortical functional connections supporting cognitive functions. Here, we use an original approach combining frequency-tagging and direct electrical stimulation (DES) to test for bidirectional and cross-hemispheric category-specific modulations within the human cortical face network. A unique patient bilaterally implanted with depth electrodes in multiple face-selective cortical regions of the ventral occipito-temporal cortex (VOTC) was shown 70 s sequences of variable natural object images at a 6 Hz rate, objectively identifying deviant face-selective neural activity at 1.2 Hz (i.e., every five images). Concurrent electrical stimulation was separately applied for 10 seconds on four independently defined face-selective sites in the right and left VOTC. Upon stimulation, we observed reduced or even abolished face-selective neural activity locally and, most interestingly, at distant VOTC recording sites. Remote DES effects were found up to the anterior temporal lobe (ATL) in both forward and backward directions along the VOTC, as well as across the two hemispheres. This reduction was specific to face-selective neural activity, with the general 6 Hz visual response being mostly unaffected. Overall, these results shed light on the functional connectivity of the cortical face-selective network, supporting its non-hierarchical organization as well as bidirectional effective category-selective connections between posterior 'core' regions and the ATL. They also pave the way for widespread and systematic development of this approach to better understand the functional and effective connectivity of human brain networks. [ABSTRACT FROM AUTHOR]

Published

2024

20. Trends and hotspots of stereoelectroencephalogram from 2002 to 2023: a bibliometric analysis

Author

Tianren Wang, Hengxin Dong, Kaiwei Li, Tao Feng, Yanfeng Yang, Sichang Chen, Di Lu, Penghu Wei, Yongzhi Shan, and Guoguang Zhao

Subjects

SEEG, bibliometrics, epilepsy, electrophysiology, neurosurgery, Neurology. Diseases of the nervous system, RC346-429

Abstract

BackgroundStereoelectroencephalography (SEEG), as a minimally invasive method that can stably collect intracranial electroencephalographic information over long periods, has increasingly been applied in the diagnosis and treatment of intractable epilepsy in recent years. Over the past 20 years, with the advancement of materials science and computer science, the application scenarios of SEEG have greatly expanded. Bibliometrics, as a method of scientifically analyzing published literature, can summarize the evolutionary process in the SEEG field and offer insights into its future development prospects.MethodsThis article selected all the literature records retrieved on November 4, 2024, from the Web of Science Core Collection (WoSCC). The search terms were as follows: “Stereo-electroencephalography” or “Stereo electroencephalography” or “Stereo-EEG” or “Stereo EEG” or “SEEG.” The document types included were research articles and reviews. For analysis, VOSviewer, CiteSpace, and the R package “bibliometrix” were employed to analyze various aspects of the SEEG field, including authors, institutions, countries and regions, and research hotspots.ResultsWe reviewed a total of 1,383 non-duplicate literature records from 2002 to 2023, including 1,241 research articles, 116 review articles and 26 letters. Observing the annual publication trends, there has been an overall increase since 2002. The most influential journal in this field is Epilepsia. Other journals with considerable impact include Clinical Neurophysiology, Epileptic Disorders, Epilepsy Research, NeuroImage, and Epilepsy & Behavior. The top 5 most influential scholars are Bartolomei F, Tassi L, Nobili L, Russo GL, and Mc Gonigal A. As for the analysis of countries and regions, France occupies a leading position in this field with its early start, while China and the United States have also emerged as focal points since 2020. Research on SEEG has expanded beyond its initial use for localizing epileptic foci and thermo-coagulation treatments and have been employed as a medium to facilitate real-time prediction of epileptic seizures and enabling the exploration of brain network connectivity.ConclusionAs a minimally invasive tool for collecting intracranial electroencephalographic signals, SEEG continues to offer vast potential for development and application. Advances in electrode materials and robotic-assisted stereotactic techniques, have enabled SEEG to simultaneously sample multiple brain regions, acquire electrical signals from deep brain structures. These advantages significantly enhance the precision of epileptic focus localization in diagnosis and treatment, addressing the limitations of subdural electrodes. Through bibliometric analysis, this paper traces the developmental trajectory of SEEG and identifying key technological milestones, thereby providing a reference for scholarly research directions.

Published

2024

21. Epilepsy lesion localization method based on brain function network.

Author

Chunying Fang, Xingyu Li, Meng Na, Wenhao Jiang, Yuankun He, Aowei Wei, Jie Huang, and Ming Zhou

Subjects

LARGE-scale brain networks, NONLINEAR functional analysis, SUPPORT vector machines, EPILEPSY, RECEIVER operating characteristic curves

Abstract

Objective: In the past, the localization of seizure onset zone (SOZ) primarily relied on traditional EEG signal analysis methods. However, due to their limited spatial and temporal resolution, accurately pinpointing neural activity was challenging, thereby restricting their clinical applicability. Compared with traditional EEG signals, SEEG signals have superior spatial and temporal resolution, and can more accurately record neural activity near epileptic foci, making them better suited for studying SOZ. In addition, the traditional EEG signal analysis methods still have limitations, mainly focusing on the analysis of local signal features, while ignoring the complexity and interconnection of the overall brain network. How to more accurately locate SOZ is still not well resolved. The purpose of this study is to develop an effective positioning method for more accurate positioning. Method: To overcome these limitations, this study proposed a model integrating brain functional network analysis with nonlinear dynamics. We utilized weighted phase lag index (WPLI) to construct brain functional network, epilepic network connectivity strength (ENCS) as the feature, and introduced persistence entropy (PE) for feature fusion, subsequently employing support vector machine (SVM) classification. Results: The proposed method was verified on the HUP-iEEG dataset, our solution identified the SOZ with 0.9440 accuracy, 0.9848 precision, 0.8974 recall rate, 0.9340 F1 score and 0.9697 area under the ROC curve across patients, which outperforms the existing approaches. It exhibits a 2.30 percentage point enhancement in localisation accuracy along with a 2.97 percentage points in AUC compared to others. Conclusion: Our method consider the interactions between nodes in brain network connections, as well as the inherent nonlinear and non-stationary properties of neural signals, to be more robust. [ABSTRACT FROM AUTHOR]

Published

2024

22. The changing landscape of electrical stimulation language mapping with subdural electrodes and stereoelectroencephalography for pediatric epilepsy: A literature review and commentary.

Author

Reecher, Hope M., Bearden, Donald J., Koop, Jennifer I., Berl, Madison M., Patrick, Kristina E., and Ailion, Alyssa S.

Subjects

*ELECTRIC stimulation, *LANDSCAPE changes, *BEHAVIORAL assessment, *EPILEPSY surgery, *NEUROLINGUISTICS, *VAGUS nerve

Abstract

Electrical stimulation mapping (ESM) is used to locate the brain areas supporting language directly within the human cortex to minimize the risk of functional decline following epilepsy surgery. ESM is completed by utilizing subdural grid or depth electrodes (stereo‐electroencephalography [sEEG]) in combination with behavioral evaluation of language. Despite technological advances, there is no standardized method of assessing language during pediatric ESM. To identify current clinical practices for pediatric ESM of language, we surveyed neuropsychologists in the Pediatric Epilepsy Research Consortium. Results indicated that sEEG is used for functional mapping at >80% of participating epilepsy surgery centers (n = 13/16) in the United States. However, >65% of sites did not report a standardized protocol to map language. Survey results indicated a clear need for practice recommendations regarding ESM of language. We then utilized PubMed/Medline and PsychInfo to identify 42 articles that reported on ESM of language, of which 18 met inclusion criteria, which included use of ESM/signal recording to localize language regions in children (<21 years) and a detailed account of the procedure and language measures used, and region‐specific language localization outcomes. Articles were grouped based on the language domain assessed, language measures used, and the brain regions involved. Our review revealed the need for evidence‐based clinical guidelines for pediatric language paradigms during ESM and a standardized language mapping protocol as well as standardized reporting of brain regions in research. Relevant limitations and future directions are discussed with a focus on considerations for pediatric language mapping. [ABSTRACT FROM AUTHOR]

Published

2024

23. Depth versus surface: A critical review of subdural and depth electrodes in intracranial electroencephalographic studies.

Author

Wu, Shasha, Issa, Naoum P., Rose, Sandra L., Haider, Hiba A., Nordli, Douglas R., Towle, Vernon L., Warnke, Peter C., and Tao, James X.

Subjects

*ELECTROENCEPHALOGRAPHY, *EPILEPSY, *ELECTRODES, *ELECTRIC stimulation, *BRAIN anatomy, *EPILEPSY surgery

Abstract

Intracranial electroencephalographic (IEEG) recording, using subdural electrodes (SDEs) and stereoelectroencephalography (SEEG), plays a pivotal role in localizing the epileptogenic zone (EZ). SDEs, employed for superficial cortical seizure foci localization, provide information on two‐dimensional seizure onset and propagation. In contrast, SEEG, with its three‐dimensional sampling, allows exploration of deep brain structures, sulcal folds, and bihemispheric networks. SEEG offers the advantages of fewer complications, better tolerability, and coverage of sulci. Although both modalities allow electrical stimulation, SDE mapping can tessellate cortical gyri, providing the opportunity for a tailored resection. With SEEG, both superficial gyri and deep sulci can be stimulated, and there is a lower risk of afterdischarges and stimulation‐induced seizures. Most systematic reviews and meta‐analyses have addressed the comparative effectiveness of SDEs and SEEG in localizing the EZ and achieving seizure freedom, although discrepancies persist in the literature. The combination of SDEs and SEEG could potentially overcome the limitations inherent to each technique individually, better delineating seizure foci. This review describes the strengths and limitations of SDE and SEEG recordings, highlighting their unique indications in seizure localization, as evidenced by recent publications. Addressing controversies in the perceived usefulness of the two techniques offers insights that can aid in selecting the most suitable IEEG in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2024

24. Posterior cingulate epilepsy: Seizure semiology and intracranial electrical stimulation using SEEG.

Author

Yan, Zhaofen, Yang, Yujiao, Wang, Jing, Deng, Qin, Zhang, Liping, Wang, Minghui, Zhou, Jian, Guan, YuGuang, Luan, Guoming, and Wang, Mengyang

Abstract

• Due to widespread connectivity of the PCC to other regions, posterior cingulate epilepsy included polymorphic semiology of the seizures. • Behavioral arrest is the most common symptoms followed by automatisms and complex motor behaviors. Autonomic seizure was very rare in PCE. • Because of the extensive reciprocal connections between PCC and hippocampus, both hippocampal and PCC lesions may serve as seizure onset zones. • The intracerebral electrical stimulation mapping of PCC was induced vestibular responses were located in the dPCC and RSC and visual responses were located in the left RSC. Autonomic responses were elicited in vPCC and RSC. This study aimed to explore seizure semiology and the effects of intracerebral electrical stimulation on the human posterior cingulate cortex (PCC) using Stereoelectroencephalography (SEEG) to deepen our comprehension of posterior cingulate epilepsy (PCE). This study examined the characteristics of seizures through video documentation, by assessing the outcomes of intracranial electrical stimulation (iES) during SEEG. We further identified the connection between the observed semiology and precise anatomical locations within the PCC subregions where seizure onset zones (SOZ) were identified. Analysis was conducted on 59 seizures from 15 patients recorded via SEEG. Behavioural arrest emerged as the predominant manifestation across the PCC subregions. Where ictal activity extended to both the mesial and lateral temporal cortex, automatism was predominantly observed in seizures originating from the ventral PCC (vPCC). The retrosplenial cortex (RSC) is associated with complex motor behaviour, with seizure discharges spreading to the temporal lobe. Seizures originating from the PCC include axial tonic and autonomic seizures. Only one case of positive clinical seizures was documented. High frequencies of iES within the PCC induced various clinical responses, categorised as vestibular, visual, psychological, and autonomic, with vestibular reactions primarily occurring in the dorsal PCC (dPCC) and RSC, visual responses in the left RSC, and autonomic reactions in the vPCC and RSC. The manifestations of seizures in PCE vary according to the SOZ and the patterns of seizure propagation. The occurrence of seizures induced by iES is exceedingly rare, indicating that mapping of the PCC could pinpoint the primary sector of PCC. [ABSTRACT FROM AUTHOR]

Published

2024

25. Ictal fast activity chirps as markers of the epileptogenic zone.

Author

Di Giacomo, Roberta, Burini, Alessandra, Chiarello, Daniela, Pelliccia, Veronica, Deleo, Francesco, Garbelli, Rita, de Curtis, Marco, Tassi, Laura, and Gnatkovsky, Vadym

Subjects

*PARTIAL epilepsy, *EPILEPSY surgery, *PEOPLE with epilepsy, *SEIZURES (Medicine), *BIOMARKERS, *TEMPORAL lobectomy, *NEUROPHYSIOLOGIC monitoring

Abstract

The identification of the epileptogenic zone (EZ) boundaries is crucial for effective focal epilepsy surgery. We verify the value of a neurophysiological biomarker of focal ictogenesis, characterized by a low‐voltage fast‐activity ictal pattern (chirp) recorded with intracerebral electrodes during invasive presurgical monitoring (stereoelectroencephalography [SEEG]). The frequency content of SEEG signals was retrospectively analyzed with semiautomatic software in 176 consecutive patients with focal epilepsies that either were cryptogenic or presented with discordant anatomoelectroclinical findings. Fast activity seizure patterns with the spectrographic features of chirps were confirmed by computer‐assisted analysis in 95.4% of patients who presented with heterogeneous etiologies and diverse lobar location of the EZ. Statistical analysis demonstrated (1) correlation between seizure outcome and concordance of sublobar regions included in the EZ defined by visual analysis and chirp‐generating regions, (2) high concordance in contact‐by contact analysis of 68 patients with Engel class Ia outcome, and (3) that discordance between chirp location and the visually outlined EZ correlated with worse seizure outcome. Seizure outcome analysis confirms the fast activity chirp pattern is a reproducible biomarker of the EZ in a heterogeneous group of patients undergoing SEEG. [ABSTRACT FROM AUTHOR]

Published

2024

26. Thalamic stereoelectroencephalography for neuromodulation target selection: Proof of concept and review of literature of pulvinar direct electrical stimulation.

Author

Ikegaya, Naoki, Aung, Thandar, Mallela, Arka, Hect, Jasmine L., Damiani, Arianna, and Gonzalez‐Martinez, Jorge A.

Subjects

*ELECTRIC stimulation, *THALAMIC nuclei, *NEUROMODULATION, *PROOF of concept, *EPILEPTIFORM discharges, *NEURAL stimulation, *TEMPORAL lobectomy

Abstract

In patients with drug‐resistant epilepsy (DRE) who are not candidates for resective surgery, various thalamic nuclei, including the anterior, centromedian, and pulvinar nuclei, have been extensively investigated as targets for neuromodulation. However, the therapeutic effects of different targets for thalamic neuromodulation on various types of epilepsy are not well understood. Here, we present a 32‐year‐old patient with multifocal bilateral temporoparieto‐occipital epilepsy and bilateral malformations of cortical development (MCDs) who underwent bilateral stereoelectroencephalographic (SEEG) recordings of the aforementioned three thalamic nuclei bilaterally. The change in the rate of interictal epileptiform discharges (IEDs) from baseline were compared in temporal, central, parietal, and occipital regions after direct electrical stimulation (DES) of each thalamic nucleus. A significant decrease in the rate of IEDs (33% from baseline) in the posterior quadrant regions was noted in the ipsilateral as well as contralateral hemisphere following DES of the pulvinar. A scoping review was also performed to better understand the current standpoint of pulvinar thalamic stimulation in the treatment of DRE. The therapeutic effect of neuromodulation can differ among thalamic nuclei targets and epileptogenic zones (EZs). In patients with multifocal EZs with extensive MCDs, personalized thalamic targeting could be achieved through DES with thalamic SEEG electrodes. [ABSTRACT FROM AUTHOR]

Published

2024

27. Modification of brain conductivity in human focal epilepsy: A model‐based estimation from stereoelectroencephalography.

Author

Lagarde, Stanislas, Modolo, Julien, Yochum, Maxime, Carvallo, Andres, Ballabeni, Alice, Scavarda, Didier, Carron, Romain, Villeneuve, Nathalie, Bartolomei, Fabrice, and Wendling, Fabrice

Subjects

*PARTIAL epilepsy, *EPILEPSY, *ELECTRIC conductivity, *EXTRACELLULAR space, *MULTIVARIATE analysis, *EPILEPSY surgery

Abstract

Objective: We have developed a novel method for estimating brain tissue electrical conductivity using low‐intensity pulse stereoelectroencephalography (SEEG) stimulation coupled with biophysical modeling. We evaluated the hypothesis that brain conductivity is correlated with the degree of epileptogenicity in patients with drug‐resistant focal epilepsy. Methods: We used bipolar low‐intensity biphasic pulse stimulation (.2 mA) followed by a postprocessing pipeline for estimating brain conductivity. This processing is based on biophysical modeling of the electrical potential induced in brain tissue between the stimulated contacts in response to pulse stimulation. We estimated the degree of epileptogenicity using a semi‐automatic method quantifying the dynamic of fast discharge at seizure onset: the epileptogenicity index (EI). We also investigated how the location of stimulation within specific anatomical brain regions or within lesional tissue impacts brain conductivity. Results: We performed 1034 stimulations of 511 bipolar channels in 16 patients. We found that brain conductivity was lower in the epileptogenic zone (EZ; unpaired median difference =.064, p <.001) and inversely correlated with the epileptogenic index value (p <.001, Spearman rho = −.32). Conductivity values were also influenced by anatomical site, location within lesion, and delay between SEEG electrode implantation and stimulation, and had significant interpatient variability. Mixed model multivariate analysis showed that conductivity is significantly associated with EI (F = 13.45, p <.001), anatomical regions (F = 5.586, p <.001), delay since implantation (F = 14.71, p =.003), and age at SEEG (F = 6.591, p =.027), but not with the type of lesion (F =.372, p =.773) or the delay since last seizure (F = 1.592, p =.235). Significance: We provide a novel model‐based method for estimating brain conductivity from SEEG low‐intensity pulse stimulations. The brain tissue conductivity is lower in EZ as compared to non‐EZ. Conductivity also varies significantly across anatomical brain regions. Involved pathophysiological processes may include changes in the extracellular space (especially volume or tortuosity) in epileptic tissue. [ABSTRACT FROM AUTHOR]

Published

2024

28. Anatomical Localization of Effective Connectivity Map Applied to Epilepsy Treatment

Author

de Arriba Senigaglia, F. Pablo J., Buenamaizón, Rocío B., Delahaye, Elisa M., Graffigna, Juan P., Schmädke, Rodolfo E. Rodríguez, Galiana, Graciana, Urquizu, Omar, Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Lopez, Natalia M., editor, and Tello, Emanuel, editor

Published

2024

29. Designing Touch: Intracortical Neurohaptic Feedback in Virtual Reality

Author

Paschall, Courtnie J., Hauptman, Jason S., Rao, Rajesh P. N., Ojemann, Jeffrey G., Herron, Jeffrey, Gan, Woon-Seng, Series Editor, Kuo, C.-C. Jay, Series Editor, Zheng, Thomas Fang, Series Editor, Barni, Mauro, Series Editor, Guger, Christoph, editor, Allison, Brendan, editor, Rutkowski, Tomasz M., editor, and Korostenskaja, Milena, editor

Published

2024

30. SEEG4D: a tool for 4D visualization of stereoelectroencephalography data

Author

James L. Evans, Matthew T. Bramlet, Connor Davey, Eliot Bethke, Aaron T. Anderson, Graham Huesmann, Yogatheesan Varatharajah, Andres Maldonado, Jennifer R. Amos, and Bradley P. Sutton

Subjects

stereoelectroencephalography, SEEG, virtual reality, presurgical planning, epilepsy, visualization tools, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Epilepsy is a prevalent and serious neurological condition which impacts millions of people worldwide. Stereoelectroencephalography (sEEG) is used in cases of drug resistant epilepsy to aid in surgical resection planning due to its high spatial resolution and ability to visualize seizure onset zones. For accurate localization of the seizure focus, sEEG studies combine pre-implantation magnetic resonance imaging, post-implant computed tomography to visualize electrodes, and temporally recorded sEEG electrophysiological data. Many tools exist to assist in merging multimodal spatial information; however, few allow for an integrated spatiotemporal view of the electrical activity. In the current work, we present SEEG4D, an automated tool to merge spatial and temporal data into a complete, four-dimensional virtual reality (VR) object with temporal electrophysiology that enables the simultaneous viewing of anatomy and seizure activity for seizure localization and presurgical planning. We developed an automated, containerized pipeline to segment tissues and electrode contacts. Contacts are aligned with electrical activity and then animated based on relative power. SEEG4D generates models which can be loaded into VR platforms for viewing and planning with the surgical team. Automated contact segmentation locations are within 1 mm of trained raters and models generated show signal propagation along electrodes. Critically, spatial–temporal information communicated through our models in a VR space have potential to enhance sEEG pre-surgical planning.

Published

2024

31. Novel cyclic homogeneous oscillation detection method for high accuracy and specific characterization of neural dynamics

Author

Hohyun Cho, Markus Adamek, Jon T Willie, and Peter Brunner

Subjects

neural oscillation, brain rhythm, EEG, ECoG, SEEG, Medicine, Science, Biology (General), QH301-705.5

Abstract

Determining the presence and frequency of neural oscillations is essential to understanding dynamic brain function. Traditional methods that detect peaks over 1/f noise within the power spectrum fail to distinguish between the fundamental frequency and harmonics of often highly non-sinusoidal neural oscillations. To overcome this limitation, we define fundamental criteria that characterize neural oscillations and introduce the cyclic homogeneous oscillation (CHO) detection method. We implemented these criteria based on an autocorrelation approach to determine an oscillation’s fundamental frequency. We evaluated CHO by verifying its performance on simulated non-sinusoidal oscillatory bursts and validated its ability to determine the fundamental frequency of neural oscillations in electrocorticographic (ECoG), electroencephalographic (EEG), and stereoelectroencephalographic (SEEG) signals recorded from 27 human subjects. Our results demonstrate that CHO outperforms conventional techniques in accurately detecting oscillations. In summary, CHO demonstrates high precision and specificity in detecting neural oscillations in time and frequency domains. The method’s specificity enables the detailed study of non-sinusoidal characteristics of oscillations, such as the degree of asymmetry and waveform of an oscillation. Furthermore, CHO can be applied to identify how neural oscillations govern interactions throughout the brain and to determine oscillatory biomarkers that index abnormal brain function.

Published

2024

32. Correspondence between scalp‐EEG and stereoelectroencephalography seizure‐onset patterns in patients with MRI‐negative drug‐resistant focal epilepsy

Author

Anna Bolzan, Jeanne Benoit, Francesca Pizzo, Julia Makhalova, Nathalie Villeneuve, Romain Carron, Didier Scavarda, Fabrice Bartolomei, and Stanislas Lagarde

Subjects

drug‐resistant epilepsy, epilepsy surgery, focal epilepsy, scalp‐EEG, SEEG, seizure‐onset pattern, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Objective Our objective was to evaluate the relationship between scalp‐EEG and stereoelectroencephalography (SEEG) seizure‐onset patterns (SOP) in patients with MRI‐negative drug‐resistant focal epilepsy. Methods We analyzed retrospectively 41 patients without visible lesion on brain MRI who underwent video‐EEG followed by SEEG. We defined five types of SOPs on scalp‐EEG and eight types on SEEG. We examined how various clinical variables affected scalp‐EEG SOPs. Results The most prevalent scalp SOPs were rhythmic sinusoidal activity (56.8%), repetitive epileptiform discharges (22.7%), and paroxysmal fast activity (15.9%). The presence of paroxysmal fast activity on scalp‐EEG was always seen without delay from clinical onset and correlated with the presence of low‐voltage fast activity in SEEG (sensitivity = 22.6%, specificity = 100%). The main factor explaining the discrepancy between the scalp and SEEG SOPs was the delay between clinical and scalp‐EEG onset. There was a correlation between the scalp and SEEG SOPs when the scalp onset was simultaneous with the clinical onset (p = 0.026). A significant delay between clinical and scalp discharge onset was observed in 25% of patients and featured always with a rhythmic sinusoidal activity on scalp, corresponding to similar morphology of the discharge on SEEG. The presence of repetitive epileptiform discharges on scalp was associated with an underlying focal cortical dysplasia (sensitivity = 30%, specificity = 90%). There was no significant association between the scalp SOP and the epileptogenic zone location (deep or superficial), or surgical outcome. Significance In patients with MRI‐negative focal epilepsy, scalp SOP could suggest the SEEG SOP and some etiology (focal cortical dysplasia) but has no correlation with surgical prognosis. Scalp SOP correlates with the SEEG SOP in cases of simultaneous EEG and clinical onset; otherwise, scalp SOP reflects the propagation of the SEEG discharge. Plain Language Summary We looked at the correspondence between the electrical activity recorded during the start of focal seizure using scalp and intracerebral electrodes in patients with no visible lesion on MRI. If there is a fast activity on scalp, it reflects similar activity inside the brain. We found a good correspondence between scalp and intracerebral electrical activity for cases without significant delay between clinical and scalp electrical onset (seen in 75% of the cases we studied). Visualizing repetitive epileptic activity on scalp could suggest a particular cause of the epilepsy: a subtype of brain malformation called focal cortical dysplasia.

Published

2024

33. Stereoelectroencephalography-guided radiofrequency thermocoagulation of the epileptogenic zone: a potential treatment and prognostic indicator for subsequent excision surgery

Author

Du, Chuan, Jin, Weipeng, Wang, Le, Yan, Jingtao, Li, Guangfeng, Wu, Yuzhang, Zhao, Guangrui, Cui, Deqiu, and Yin, Shaoya

Published

2024

34. Frame-based versus robot-assisted stereo-electro-encephalography for drug-resistant epilepsy

Author

Han, Chang-Lin, Chou, Chien-Chen, Chen, Hsin-Hung, Chen, Yi-Hsiu, Lin, Chun-Fu, Chen, Chien, Yu, Hsiang-Yu, Chen, Yu-Wei, and Lee, Cheng-Chia

Published

2024

35. SEEG study of a rare male temporal lobe epilepsy with orgasmic aura originating from the right amygdala

Author

Xia, Chunsheng, Wang, Lanlan, Zhang, Dong, You, Longfei, Zhang, Yiming, Qi, Yinbao, Liu, Xiang, and Qian, Ruobing

Published

2024

36. Boltless nylon-suture technique for stereotactic electroencephalography as a safe, effective alternative when the anchor bolt is inappropriate

Author

Mutoh, Manabu, Maesawa, Satoshi, Nakatsubo, Daisuke, Ishizaki, Tomotaka, Tanei, Takafumi, Torii, Jun, Ito, Yoshiki, Hashida, Miki, and Saito, Ryuta

Published

2024

37. Feasibility and safety of stereoelectroencephalography in young children.

Author

Muh, Carrie R., Dorilio, Jessica R., Beaudreault, Cameron P., McGoldrick, Patricia E., Pisapia, Jared M., and Wolf, Steven M.

Subjects

*EUCLIDEAN distance, *SURGICAL complications, *COMPUTED tomography, *PEOPLE with epilepsy, *TEMPORAL lobectomy, *SKULL

Abstract

Purpose: Stereoelectroencephalography (SEEG) is a diagnostic surgery that implants electrodes to identify areas of epileptic onset in patients with drug-resistant epilepsy (DRE). SEEG is effective in identifying the epileptic zone; however, placement of electrodes in very young children has been considered contraindicated due to skull thinness. The goal of this study was to evaluate if SEEG is safe and accurate in young children with thin skulls. Methods: Four children under the age of two years old with DRE underwent SEEG to locate the region of seizure onset. Presurgical planning and placement of electrodes were performed using ROSA One Brain. Preoperative electrode plans were merged with postoperative CT scans to determine accuracy. Euclidean distance between the planned and actual trajectories was calculated using a 3D coordinate system at both the entry and target points for each electrode. Results: Sixty-three electrodes were placed among four patients. Mean skull thickness at electrode entry sites was 2.34 mm. The mean difference between the planned and actual entry points was 1.12 mm, and the mean difference between the planned and actual target points was 1.73 mm. No significant correlation was observed between planned and actual target points and skull thickness (Pearson R = − 0.170). No perioperative or postoperative complications were observed. Conclusions: This study demonstrates that SEEG can be safe and accurate in children under two years of age despite thin skulls. SEEG should be considered for young children with DRE, and age and skull thickness are not definite contraindications to the surgery. [ABSTRACT FROM AUTHOR]

Published

2024

38. Multiscale neuro-inspired models for interpretation of EEG signals in patients with epilepsy.

Author

Wendling, Fabrice, Koksal-Ersoz, Elif, Al-Harrach, Mariam, Yochum, Maxime, Merlet, Isabelle, Ruffini, Giulio, Bartolomei, Fabrice, and Benquet, Pascal

Subjects

*PEOPLE with epilepsy, *MULTISCALE modeling, *ELECTROENCEPHALOGRAPHY, *EPILEPTIFORM discharges, *NEURAL circuitry, *PYRAMIDAL neurons

Abstract

• Neuro-inspired computational models of human cortex developed at three levels (cellular, assembly and whole brain) are described. • Models explain the cell- and network-related mechanisms underlying the generation of i) fast ripples and ii) SEEG- and EEG-recorded epileptic spikes and spike-waves. • The knowledge gained from these models effectively complements the clinical analysis of SEEG data collected during the evaluation of patients with epilepsy. The aim is to gain insight into the pathophysiological mechanisms underlying interictal epileptiform discharges observed in electroencephalographic (EEG) and stereo-EEG (SEEG, depth electrodes) recordings performed during pre-surgical evaluation of patients with drug-resistant epilepsy. We developed novel neuro-inspired computational models of the human cerebral cortex at three different levels of description: i) microscale (detailed neuron models), ii) mesoscale (neuronal mass models) and iii) macroscale (whole brain models). Although conceptually different, micro- and mesoscale models share some similar features, such as the typology of neurons (pyramidal cells and three types of interneurons), their spatial arrangement in cortical layers, and their synaptic connectivity (excitatory and inhibitory). The whole brain model consists of a large-scale network of interconnected neuronal masses, with connectivity based on the human connectome. For these three levels of description, the fine-tuning of free parameters and the quantitative comparison with real data allowed us to reproduce interictal epileptiform discharges with a high degree of fidelity and to formulate hypotheses about the cell- and network-related mechanisms underlying the generation of fast ripples and SEEG-recorded epileptic spikes and spike-waves. The proposed models provide valuable insights into the pathophysiological mechanisms underlying the generation of epileptic events. The knowledge gained from these models effectively complements the clinical analysis of SEEG data collected during the evaluation of patients with epilepsy. These models are likely to play a key role in the mechanistic interpretation of epileptiform activity. [ABSTRACT FROM AUTHOR]

Published

2024

39. Distributed source modeling of stereoencephalographic measurements of ictal activity.

Author

Lee, Hsin-Ju, Chien, Lin-Yao, Yu, Hsiang-Yu, Lee, Cheng-Chia, Chou, Chien-Chen, Kuo, Wen-Jui, and Lin, Fa-Hsuan

Subjects

*ELECTRICAL impedance tomography, *TEMPORAL lobectomy, *MAGNETIC resonance imaging, *SAMPLING errors, *SENSITIVITY & specificity (Statistics), *SURGICAL excision

Abstract

• Stereoelectroencephalography (SEEG) can have incomplete or inadequate sampling of the epileptogenic zone (EZ). • Distributed source modeling on the SEEG data can mitigate the challenge of the sampling error. • The sub-sampled data with at least one contact no more than 20 mm away from the EZ gave the comparable EZ detection. Stereoelectroencephalography (SEEG) can define the epileptogenic zone (EZ). However, SEEG is susceptible to the sampling bias, where no SEEG recording is taken within a circumscribed EZ. Nine patients with medically refractory epilepsy underwent SEEG recording, and brain resection got positive outcomes. Ictal neuronal currents were estimated by distributed source modeling using the SEEG data and individual's anatomical magnetic resonance imaging. Using a retrospective leave-one-out data sub-sampling, we evaluated the sensitivity and specificity of the current estimates using MRI after surgical resection or radio-frequency ablation. The sensitivity and specificity in detecting the EZ were indistinguishable from either the data from all electrodes or the sub-sampled data (rank sum test: rank sum = 23719, p = 0.13) when at least one remaining electrode contact was no more than 20 mm away. The distributed neuronal current estimates of ictal SEEG data can mitigate the challenge of delineating the boundary of the EZ in cases of missing an electrode implanted within the EZ and a required second SEEG exploration. Distributed source modeling can be a tool for clinicians to infer the EZ by allowing for more flexible planning of the electrode implantation route and minimizing the number of electrodes. [ABSTRACT FROM AUTHOR]

Published

2024

40. A scoping review of seizure onset pattern in SEEG and a proposal for morphological classification.

Author

Yindeedej, Vich, Uda, Takehiro, Tanoue, Yuta, Kojima, Yuichiro, Kawashima, Toshiyuki, Koh, Saya, Uda, Hiroshi, Nishiyama, Taro, Takagawa, Masanari, Shuto, Futoshi, and Goto, Takeo

Abstract

• Seizure onset pattern (SOP) represents an alteration of electroencephalography (EEG) morphology at the beginning of seizure. • Many morphological SOP classifications have been reported without established consensus in stereotactic electroencephalography (SEEG). Some types of SOP were quite similar, but named differently between each report, which make difficulties to communicate among doctors. • From this review, SOP can be classified into five major types including 1.Low voltage fast activity (LVFA), 2.Sharp activity, 3.Burst of polyspikes, 4.Periodic polyspikes (with one special subtype; Delta brush) and 5.Spike and wave (with one special subtype; Low-frequency, high-amplitude periodic spike [LFPS]). • A clear algorithm for determining SOP morphology was also proposed. The issue of clinical correlation to SOP will be further studied after a systematic classification is established and generalized. Seizure onset pattern (SOP) represents an alteration of electroencephalography (EEG) morphology at the beginning of seizure activity in epilepsy. With stereotactic electroencephalography (SEEG), a method for intracranial EEG evaluation, many morphological SOP classifications have been reported without established consensus. These inconsistent classifications with ambiguous terminology present difficulties to communication among epileptologists. We reviewed SOP in SEEG by searching the PubMed database. Reported morphological classifications and the ambiguous terminology used were collected. After thoroughly reviewing all reports, we reconsidered the definitions of these terms and explored a more consistent and simpler morphological SOP classification. Of the 536 studies initially found, 14 studies were finally included after screening and excluding irrelevant studies. We reconsidered the definitions of EEG onset, period for determining type of SOP, core electrode and other terms in SEEG. We proposed a more consistent and simpler morphological SOP classification comprising five major types with two special subtypes. A scoping review of SOP in SEEG was performed. Our classification may be suitable for describing SOP morphology. [ABSTRACT FROM AUTHOR]

Published

2024

41. The Association Between Trajectory-Skull Angle and Accuracy of Stereoelectroencephalography Electrode Implantation in Drug-Resistant Epilepsy.

Author

Du, Chuan, Wang, Le, Yan, Jingtao, Li, Guangfeng, Wu, Yuzhang, Zhao, Guangrui, Cui, Deqiu, Jin, Weipeng, and Yin, Shaoya

Subjects

*STEREOTAXIC techniques, *EPILEPSY, *ELECTRODES, *COMPUTED tomography, *ANGLES, *CURVE fitting

Abstract

To analyze the relationship between trajectory-skull angle and stereoelectroencephalography electrode implantation accuracy in drug-resistant epilepsy patients, aiming to guide clinical electrode placement and enhance surgical precision and safety. We conducted a retrospective analysis of medical records and surgical characteristics of 32 consecutive patients diagnosed with drug-resistant epilepsy, who underwent stereoelectroencephalography procedures at our center from June 2020 to June 2023. To evaluate the accuracy of electrode implantation, we utilized preoperative and postoperative computed tomography scans fused with SinoPlan software-planned trajectories. Entry radial error and target vector error were assessed as measurements of electrode implantation accuracy. After adjusting for confounders, we found a significant positive correlation between trajectory-skull angle and entry radial error (β = 0.02, 95% CI: 0.01–0.03, P < 0.001). Likewise, a significant positive correlation existed between trajectory-skull angle and target vector error in all three models (β = 0.03, 95% CI: 0.01–0.04, P < 0.001). Additionally, a U-shaped relationship between trajectory-skull angle and target vector error was identified using smooth curve fitting. This U-shaped pattern persisted in both frame-based and robot-guided stereotactic techniques. According to the two-piecewise linear regression model, the inflection points were 9° in the frame-based group and 16° in the robot-guided group. This study establishes a significant positive linear correlation between trajectory-skull angle and entry radial error, along with a distinctive U-shaped pattern in the relationship between trajectory-skull angle and target vector error. Our findings suggest that trajectory-skull angles of 9° (frame-based) and 16° (robot-guided) may optimize the accuracy of target vector error. [ABSTRACT FROM AUTHOR]

Published

2024

42. Correspondence between scalp‐EEG and stereoelectroencephalography seizure‐onset patterns in patients with MRI‐negative drug‐resistant focal epilepsy.

Author

Bolzan, Anna, Benoit, Jeanne, Pizzo, Francesca, Makhalova, Julia, Villeneuve, Nathalie, Carron, Romain, Scavarda, Didier, Bartolomei, Fabrice, and Lagarde, Stanislas

Abstract

Objective: Our objective was to evaluate the relationship between scalp‐EEG and stereoelectroencephalography (SEEG) seizure‐onset patterns (SOP) in patients with MRI‐negative drug‐resistant focal epilepsy. Methods: We analyzed retrospectively 41 patients without visible lesion on brain MRI who underwent video‐EEG followed by SEEG. We defined five types of SOPs on scalp‐EEG and eight types on SEEG. We examined how various clinical variables affected scalp‐EEG SOPs. Results: The most prevalent scalp SOPs were rhythmic sinusoidal activity (56.8%), repetitive epileptiform discharges (22.7%), and paroxysmal fast activity (15.9%). The presence of paroxysmal fast activity on scalp‐EEG was always seen without delay from clinical onset and correlated with the presence of low‐voltage fast activity in SEEG (sensitivity = 22.6%, specificity = 100%). The main factor explaining the discrepancy between the scalp and SEEG SOPs was the delay between clinical and scalp‐EEG onset. There was a correlation between the scalp and SEEG SOPs when the scalp onset was simultaneous with the clinical onset (p = 0.026). A significant delay between clinical and scalp discharge onset was observed in 25% of patients and featured always with a rhythmic sinusoidal activity on scalp, corresponding to similar morphology of the discharge on SEEG. The presence of repetitive epileptiform discharges on scalp was associated with an underlying focal cortical dysplasia (sensitivity = 30%, specificity = 90%). There was no significant association between the scalp SOP and the epileptogenic zone location (deep or superficial), or surgical outcome. Significance: In patients with MRI‐negative focal epilepsy, scalp SOP could suggest the SEEG SOP and some etiology (focal cortical dysplasia) but has no correlation with surgical prognosis. Scalp SOP correlates with the SEEG SOP in cases of simultaneous EEG and clinical onset; otherwise, scalp SOP reflects the propagation of the SEEG discharge. Plain Language Summary: We looked at the correspondence between the electrical activity recorded during the start of focal seizure using scalp and intracerebral electrodes in patients with no visible lesion on MRI. If there is a fast activity on scalp, it reflects similar activity inside the brain. We found a good correspondence between scalp and intracerebral electrical activity for cases without significant delay between clinical and scalp electrical onset (seen in 75% of the cases we studied). Visualizing repetitive epileptic activity on scalp could suggest a particular cause of the epilepsy: a subtype of brain malformation called focal cortical dysplasia. [ABSTRACT FROM AUTHOR]

Published

2024

43. Speech decoding using cortical and subcortical electrophysiological signals.

Author

Hemmings Wu, Chengwei Cai, Wenjie Ming, Wangyu Chen, Zhoule Zhu, Chen Feng, Hongjie Jiang, Zhe Zheng, Sawan, Mohamad, Ting Wang, and Junming Zhu

Subjects

SPEECH, TONE (Phonetics), VOWELS, TEMPORAL lobe, ELECTROPHYSIOLOGY, CEREBRAL cortex, BRAIN anatomy

Abstract

Introduction: Language impairments often result from severe neurological disorders, driving the development of neural prosthetics utilizing electrophysiological signals to restore comprehensible language. Previous decoding efforts primarily focused on signals from the cerebral cortex, neglecting subcortical brain structures' potential contributions to speech decoding in braincomputer interfaces. Methods: In this study, stereotactic electroencephalography (sEEG) was employed to investigate subcortical structures' role in speech decoding. Two native Mandarin Chinese speakers, undergoing sEEG implantation for epilepsy treatment, participated. Participants read Chinese text, with 1-30, 30-70, and 70-150 Hz frequency band powers of sEEG signals extracted as key features. A deep learning model based on long short-term memory assessed the contribution of different brain structures to speech decoding, predicting consonant articulatory place, manner, and tone within single syllable. Results: Cortical signals excelled in articulatory place prediction (86.5% accuracy), while cortical and subcortical signals performed similarly for articulatory manner (51.5% vs. 51.7% accuracy). Subcortical signals provided superior tone prediction (58.3% accuracy). The superior temporal gyrus was consistently relevant in speech decoding for consonants and tone. Combining cortical and subcortical inputs yielded the highest prediction accuracy, especially for tone. Discussion: This study underscores the essential roles of both cortical and subcortical structures in different aspects of speech decoding. [ABSTRACT FROM AUTHOR]

Published

2024

44. Implantation accuracy of novel polyimide stereotactic electroencephalographic depth electrodes--a human cadaveric study.

Author

Kullmann, Aura, Akberali, Farida, Van Gompel, Jaime J., McGovern, Robert A., Marsh, W. Richard, Kridner, Debra, Diaz-Botia, Camilo A., and Park, Michael C.

Subjects

EPILEPSY surgery, NEUROSURGERY, RESEARCH funding, T-test (Statistics), ELECTROENCEPHALOGRAPHY, MEDICAL cadavers, QUESTIONNAIRES, COMPUTED tomography, ARTIFICIAL implants, MINIMALLY invasive procedures, RADIO frequency therapy, DESCRIPTIVE statistics, SIMULATION methods in education, STEREOTAXIC techniques, CLINICAL competence, ROBOTICS, ANALYSIS of variance, NATIONAL competency-based educational tests, CATHETER ablation, DATA analysis software, ELECTRODES, MEDICAL practice

Abstract

Introduction: Stereoelectroencephalography (sEEG) is a minimally invasive procedure that uses depth electrodes stereotactically implanted into brain structures to map the origin and propagation of seizures in epileptic patients. Implantation accuracy of sEEG electrodes plays a critical role in the safety and efficacy of the procedure. This study used human cadaver heads, simulating clinical practice, to evaluate (1) neurosurgeon's ability to implant a new thin- film polyimide sEEG electrode according to the instructions for use (IFU), and (2) implantation accuracy. Methods: Four neurosurgeons (users) implanted 24 sEEG electrodes into two cadaver heads with the aid of the ROSA robotic system. Usability was evaluated using a questionnaire that assessed completion of all procedure steps per IFU and user errors. For implantation accuracy evaluation, planned electrode trajectories were compared with post-implantation trajectories after fusion of pre- and postoperative computer tomography (CT) images. Implantation accuracy was quantified using the Euclidean distance for entry point error (EPE) and target point error (TPE). Results: All sEEG electrodes were successfully placed following the IFU without user errors, and post-implant survey of users showed favorable handling characteristics. The EPE was 1.28 ± 0.86 mm and TPE was 1.61 ± 0.89 mm. Long trajectories (>50 mm) had significantly larger EPEs and TPEs than short trajectories (<50 mm), and no differences were found between orthogonal and oblique trajectories. Accuracies were similar or superior to those reported in the literature when using similar experimental conditions, and in the same range as those reported in patients. Discussion: The results demonstrate that newly developed polyimide sEEG electrodes can be implanted as accurately as similar devices in the marker without user errors when following the IFU in a simulated clinical environment. The human cadaver ex-vivo test system provided a realistic test system, owing to the size, anatomy and similarity of tissue composition to that of the live human brain. [ABSTRACT FROM AUTHOR]

Published

2024

45. Speech synthesis from intracranial stereotactic Electroencephalography using a neural vocoder.

Author

Arthur, Frigyes Viktor and Csapó, Tamás Gábor

Subjects

*ARTIFICIAL neural networks, *VOCODER, *ELECTROENCEPHALOGRAPHY, *SPEECH synthesis, *BRAIN-computer interfaces, *SPEECH, *STEREOTAXIC techniques

Abstract

Speech is one of the most important human bio-signals. However, only some speech production characteristics are fully understood, which are required for a successful speech-based Brain-Computer Interface (BCI). A proper brain-to-speech system that can generate the speech of full sentences intelligibly and naturally poses a great challenge. In our study, we used the SingleWordProduction-Dutch-iBIDS dataset, in which speech and intracranial stereotactic electroencephalography (sEEG) signals of the brain were recorded simultaneously during a single word production task. We apply deep neural networks (FC-DNN, 2D-CNN, and 3D-CNN) on the ten speakers’ data for sEEG-to-Mel spectrogram prediction. Next, we synthesize speech using the WaveGlow neural vocoder. Our objective and subjective evaluations have shown that the DNN-based approaches with neural vocoder outperform the baseline linear regression model using Griffin-Lim. The synthesized samples resemble the original speech but are still not intelligible, and the results are clearly speaker dependent. In the long term, speech-based BCI applications might be useful for the speaking impaired or those having neurological disorders. [ABSTRACT FROM AUTHOR]

Published

2024

46. Attentional control influence habituation through modulation of connectivity patterns within the prefrontal cortex: Insights from stereo-EEG

Author

Huimin Huang, Rui Li, Xiaojun Qiao, Xiaoran Li, Ziyue Li, Siyi Chen, Yi Yao, Fengpeng Wang, Xiaobin Zhang, Kaomin Lin, and Junsong Zhang

Subjects

Attentional control, Habituation, Connectivity patterns, Top-down, SEEG, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Attentional control, guided by top-down processes, enables selective focus on pertinent information, while habituation, influenced by bottom-up factors and prior experiences, shapes cognitive responses by emphasizing stimulus relevance. These two fundamental processes collaborate to regulate cognitive behavior, with the prefrontal cortex and its subregions playing a pivotal role. Nevertheless, the intricate neural mechanisms underlying the interaction between attentional control and habituation are still a subject of ongoing exploration. To our knowledge, there is a dearth of comprehensive studies on the functional connectivity between subsystems within the prefrontal cortex during attentional control processes in both primates and humans. Utilizing stereo-electroencephalogram (SEEG) recordings during the Stroop task, we observed top-down dominance effects and corresponding connectivity patterns among the orbitofrontal cortex (OFC), the middle frontal gyrus (MFG), and the inferior frontal gyrus (IFG) during heightened attentional control. These findings highlighting the involvement of OFC in habituation through top-down attention. Our study unveils unique connectivity profiles, shedding light on the neural interplay between top-down and bottom-up attentional control processes, shaping goal-directed attention.

Published

2024

47. Utility of adding electrodes in patients undergoing invasive seizure localization: A case series.

Author

Chan, Alvin Y, Lien, Brian V, Brown, Nolan J, Gendreau, Julian, Beyer, Ryan S, Yang, Chen Yi, Choi, Elliot H, Hsu, Frank PK, and Vadera, Sumeet

Subjects

Electrode, Epilepsy, SEEG, Seizure, Stereoelectroencephalography, Subdural grid, Patient Safety, Brain Disorders, Neurosciences, Clinical Research, Neurodegenerative, Neurological

Abstract

IntroductionSurgery can be an effective treatment for epilepsy if the seizure onset is adequately localized. Invasive monitoring is used if noninvasive methods are inconclusive. Initial invasive monitoring may fail if the pre-surgical hypothesis regarding location of epileptic foci is wrong. At this point, a decision must be made whether to remove all electrodes without a clearly defined location of onset or to implant additional electrodes with the aim of achieving localization by expanding coverage.MethodsElectrodes were placed according to a hypothesis derived from noninvasive monitoring techniques in adult patients with long term epilepsy. Seizure onset was not clearly localized at the end of the invasive monitoring period in ten patients, and additional electrodes were placed based on a new hypothesis that incorporated data from the invasive monitoring period.ResultsSuccessful localization was achieved in nine patients. There were no complications with adding additional electrodes. At final follow up, four patients were seizure free while four others had at least a 50% reduction in seizures after undergoing surgical intervention.ConclusionSeizure foci were localized safely in 90% of adult patients with long term epilepsy after implanting additional electrodes and expanding coverage. Patients undergoing invasive monitoring without clear localization should have additional electrodes placed to expand monitoring coverage as it is safe and effective.

Published

2022

48. Characterization of low‐grade epilepsy‐associated tumor from implanted stereoelectroencephalography electrodes

Author

Taylor A. Gatesman, Jasmine L. Hect, H. Westley Phillips, Brenden J. Johnson, Abigail I. Wald, Colleen McClung, Marina N. Nikiforova, John M. Skaugen, Ian F. Pollack, Taylor J. Abel, and Sameer Agnihotri

Subjects

LEATs, methylation, mutation, sEEG, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Low‐grade epilepsy‐associated tumors (LEATs) are a common cause of drug‐resistant epilepsy in children. Herein, we demonstrate the feasibility of using tumor tissue derived from stereoelectroencephalography (sEEG) electrodes upon removal to molecularly characterize tumors and aid in diagnosis. An 18‐year‐old male with focal epilepsy and MRI suggestive of a dysembryoplastic neuroepithelial tumor (DNET) in the left posterior temporal lobe underwent implantation of seven peri‐tumoral sEEG electrodes for peri‐operative language mapping and demarcation of the peri‐tumoral ictal zone prior to DNET resection. Using electrodes that passed through tumor tissue, we show successful isolation of tumor DNA and subsequent analysis using standard methods for tumor classification by DNA, including Glioseq targeted sequencing and DNA methylation array analysis. This study provides preliminary evidence for the feasibility of molecular diagnosis of LEATs or other lesions using a minimally invasive method with microscopic tissue volumes. The implications of sEEG electrodes in tumor characterization are broad but would aid in diagnosis and subsequent targeted therapeutic strategies.

Published

2024

49. Organization of the epileptogenic zone and signal analysis at seizure onset in patients with drug‐resistant epilepsy due to focal cortical dysplasia with mTOR pathway gene mutations—An SEEG study

Author

Irina Oane, Andrei Barborica, Andrei Daneasa, Mihai Dragos Maliia, Jean Ciurea, Sergiu Stoica, Aurelia Dabu, Flavius Bratu, Camelia Lentoiu, and Ioana Mindruta

Subjects

epilepsy surgery, focal cortical dysplasia, mTOR mutation, SEEG, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Epilepsy surgery in genetic drug‐resistant epilepsy is a debated subject as more histological and molecular data are available. We retrospectively collected data from focal drug‐resistant epilepsy patients that underwent stereoelectroencephalography (SEEG) invasive recordings. Patients with nonlesional brain imaging or in whom a first epilepsy surgery failed to control seizures were selected. We computed and displayed the intracranial ictal onset activity pattern on structural imaging. Patients underwent epilepsy gene panel testing, next generation sequencing—NGS. Of 113 patients, 13 underwent genetic testing, and in 6 patients, a mechanistic target of rapamycin pathway gene germline mutation (mTOR) was identified. Brain imaging was nonlesional except for one patient in whom two abnormalities suggestive of focal cortical dysplasia (FCD) were found. Patients underwent tailored brain surgery based on SEEG data, tissue analysis revealed FCD and postsurgical outcome was favorable. Our findings are similar to previous case series suggesting that epilepsy surgery can be a treatment option in patients with mTOR pathway mutation. In patients with mTOR pathway mutation, the postsurgical outcome is favorable if complete resection of the epileptogenic zone is performed. Electrophysiological seizure onset patterns in FCDs associated with mTOR pathway mutations display low‐voltage fast activity as previously described.

Published

2023

50. Stereo-EEG-guided network modulation for psychiatric disorders: Interactive holographic planning

Author

Angela M. Noecker, Jeffrey Mlakar, Kelly R. Bijanki, Mark A. Griswold, Nader Pouratian, Sameer A. Sheth, and Cameron C. McIntyre

Subjects

sEEG, DBS, Depression, HoloLens, Visualization, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Background: Connectomic modeling studies are expanding understanding of the brain networks that are modulated by deep brain stimulation (DBS) therapies. However, explicit integration of these modeling results into prospective neurosurgical planning is only beginning to evolve. One challenge of employing connectomic models in patient-specific surgical planning is the inherent 3D nature of the results, which can make clinically useful data integration and visualization difficult. Methods: We developed a holographic stereotactic neurosurgery research tool (HoloSNS) that integrates patient-specific brain models into a group-based visualization environment for interactive surgical planning using connectomic hypotheses. HoloSNS currently runs on the HoloLens 2 platform and it enables remote networking between headsets. This allowed us to perform surgical planning group meetings with study co-investigators distributed across the country. Results: We used HoloSNS to plan stereo-EEG and DBS electrode placements for each patient participating in a clinical trial (NCT03437928) that is targeting both the subcallosal cingulate and ventral capsule for the treatment of depression. Each patient model consisted of multiple components of scientific data and anatomical reconstructions of the head and brain (both patient-specific and atlas-based), which far exceed the data integration capabilities of traditional neurosurgical planning workstations. This allowed us to prospectively discuss and evaluate the positioning of the electrodes based on novel connectomic hypotheses. Conclusions: The 3D nature of the surgical procedure, brain imaging data, and connectomic modeling results all highlighted the utility of employing holographic visualization to support the design of unique clinical experiments to explore brain network modulation with DBS.

Published

2023