Your search keyword '"Staba, Richard"' showing total 506 results

1. PyHFO: lightweight deep learning-powered end-to-end high-frequency oscillations analysis application.

Author

Zhang, Yipeng, Liu, Lawrence, Ding, Yuanyi, Chen, Xin, Monsoor, Tonmoy, Daida, Atsuro, Oana, Shingo, Hussain, Shaun, Sankar, Raman, Fallah, Aria, Santana-Gomez, Cesar, Speier, William, Zhang, Jianguo, Nariai, Hiroki, Staba, Richard, Engel, Jerome, and Roychowdhury, Vwani

Subjects

convolutional neural networks, high-frequency oscillations, neurophysiology, Deep Learning, Electroencephalography, Animals, Rats, Algorithms, Epilepsy, Software, Humans, Hippocampus

Abstract

Objective. This study aims to develop and validate an end-to-end software platform, PyHFO, that streamlines the application of deep learning (DL) methodologies in detecting neurophysiological biomarkers for epileptogenic zones from EEG recordings.Approach. We introduced PyHFO, which enables time-efficient high-frequency oscillation (HFO) detection algorithms like short-term energy and Montreal Neurological Institute and Hospital detectors. It incorporates DL models for artifact and HFO with spike classification, designed to operate efficiently on standard computer hardware.Main results. The validation of PyHFO was conducted on three separate datasets: the first comprised solely of grid/strip electrodes, the second a combination of grid/strip and depth electrodes, and the third derived from rodent studies, which sampled the neocortex and hippocampus using depth electrodes. PyHFO demonstrated an ability to handle datasets efficiently, with optimization techniques enabling it to achieve speeds up to 50 times faster than traditional HFO detection applications. Users have the flexibility to employ our pre-trained DL model or use their EEG data for custom model training.Significance. PyHFO successfully bridges the computational challenge faced in applying DL techniques to EEG data analysis in epilepsy studies, presenting a feasible solution for both clinical and research settings. By offering a user-friendly and computationally efficient platform, PyHFO paves the way for broader adoption of advanced EEG data analysis tools in clinical practice and fosters potential for large-scale research collaborations.

Published

2024

2. Different Trajectories of Functional Connectivity Captured with Gamma-Event Coupling and Broadband Measures of Electroencephalographic in the Rat Fluid Percussion Injury Model

Author

Fox, Rachel, Santana-Gomez, Cesar, Shamas, Mohamad, Pavade, Aarja, Staba, Richard, and Harris, Neil G

Subjects

Biomedical and Clinical Sciences, Neurosciences, Neurodegenerative, Brain Disorders, Physical Injury - Accidents and Adverse Effects, 2.1 Biological and endogenous factors, Neurological, electroencephalography, network, resting state, sleep, traumatic brain injury

Published

2024

3. The Surgical Method of Craniectomy Differentially Affects Acute Seizures, Brain Deformation, and Behavior in a Traumatic Brain Injury Animal Model

Author

Santana-Gomez, Cesar, Smith, Gregory, Mousavi, Ava, Shamas, Mohamad, Harris, Neil G, and Staba, Richard

Subjects

Biomedical and Clinical Sciences, Engineering, Biomedical Engineering, Neurosciences, Brain Disorders, Neurodegenerative, Epilepsy, Traumatic Head and Spine Injury, Traumatic Brain Injury (TBI), Physical Injury - Accidents and Adverse Effects, Injuries and accidents, Neurological, acute seizure activity, craniectomy method, EEG, traumatic brain injury

Published

2024

4. Epilepsy phenotype and its reproducibility after lateral fluid percussion‐induced traumatic brain injury in rats: Multicenter EpiBioS4Rx study project 1

Author

Ndode‐Ekane, Xavier Ekolle, Ali, Idrish, Santana‐Gomez, Cesar, Andrade, Pedro, Immonen, Riikka, Casillas‐Espinosa, Pablo, Paananen, Tomi, Manninen, Eppu, Puhakka, Noora, Smith, Gregory, Brady, Rhys D, Silva, Juliana, Braine, Emma, Hudson, Matt, Yamakawa, Glen R, Jones, Nigel C, Shultz, Sandy R, Harris, Neil, Wright, David K, Gröhn, Olli, Staba, Richard, O'Brien, Terence J, and Pitkänen, Asla

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Neurodegenerative, Epilepsy, Traumatic Brain Injury (TBI), Traumatic Head and Spine Injury, Physical Injury - Accidents and Adverse Effects, Brain Disorders, Neurological, Animals, Male, Rats, Brain Injuries, Traumatic, Disease Models, Animal, Epilepsy, Post-Traumatic, Percussion, Phenotype, Rats, Sprague-Dawley, Reproducibility of Results, Seizures, harmonization, posttraumatic epilepsy, preclinical, video-EEG monitoring, Neurology & Neurosurgery, Clinical sciences

Abstract

ObjectiveThis study was undertaken to assess reproducibility of the epilepsy outcome and phenotype in a lateral fluid percussion model of posttraumatic epilepsy (PTE) across three study sites.MethodsA total of 525 adult male Sprague Dawley rats were randomized to lateral fluid percussion-induced brain injury (FPI) or sham operation. Of these, 264 were assigned to magnetic resonance imaging (MRI cohort, 43 sham, 221 traumatic brain injury [TBI]) and 261 to electrophysiological follow-up (EEG cohort, 41 sham, 220 TBI). A major effort was made to harmonize the rats, materials, equipment, procedures, and monitoring systems. On the 7th post-TBI month, rats were video-EEG monitored for epilepsy diagnosis.ResultsA total of 245 rats were video-EEG phenotyped for epilepsy on the 7th postinjury month (121 in MRI cohort, 124 in EEG cohort). In the whole cohort (n = 245), the prevalence of PTE in rats with TBI was 22%, being 27% in the MRI and 18% in the EEG cohort (p > .05). Prevalence of PTE did not differ between the three study sites (p > .05). The average seizure frequency was .317 ± .725 seizures/day at University of Eastern Finland (UEF; Finland), .085 ± .067 at Monash University (Monash; Australia), and .299 ± .266 at University of California, Los Angeles (UCLA; USA; p  .05). Of the 219 seizures, 53% occurred as part of a seizure cluster (≥3 seizures/24 h; p >.05 between the study sites). Of the 209 seizures, 56% occurred during lights-on period and 44% during lights-off period (p > .05 between the study sites).SignificanceThe PTE phenotype induced by lateral FPI is reproducible in a multicenter design. Our study supports the feasibility of performing preclinical multicenter trials in PTE to increase statistical power and experimental rigor to produce clinically translatable data to combat epileptogenesis after TBI.

Published

2024

5. Simulated resections and responsive neurostimulator placement can optimize postoperative seizure outcomes when guided by fast ripple networks.

Author

Weiss, Shennan, Sperling, Michael, Engel, Jerome, Liu, Anli, Fried, Itzhak, Wu, Chengyuan, Doyle, Werner, Mikell, Charles, Mofakham, Sima, Salamon, Noriko, Sim, Myung, Bragin, Anatol, and Staba, Richard

Subjects

epilepsy surgery, fast ripple, high-frequency oscillation, neuromodulation, virtual resection

Abstract

In medication-resistant epilepsy, the goal of epilepsy surgery is to make a patient seizure free with a resection/ablation that is as small as possible to minimize morbidity. The standard of care in planning the margins of epilepsy surgery involves electroclinical delineation of the seizure-onset zone and incorporation of neuroimaging findings from MRI, PET, single-photon emission CT and magnetoencephalography modalities. Resecting cortical tissue generating high-frequency oscillations has been investigated as a more efficacious alternative to targeting the seizure-onset zone. In this study, we used a support vector machine (SVM), with four distinct fast ripple (FR: 350-600 Hz on oscillations, 200-600 Hz on spikes) metrics as factors. These metrics included the FR resection ratio, a spatial FR network measure and two temporal FR network measures. The SVM was trained by the value of these four factors with respect to the actual resection boundaries and actual seizure-free labels of 18 patients with medically refractory focal epilepsy. Leave-one-out cross-validation of the trained SVM in this training set had an accuracy of 0.78. We next used a simulated iterative virtual resection targeting the FR sites that were of highest rate and showed most temporal autonomy. The trained SVM utilized the four virtual FR metrics to predict virtual seizure freedom. In all but one of the nine patients who were seizure free after surgery, we found that the virtual resections sufficient for virtual seizure freedom were larger in volume (P < 0.05). In nine patients who were not seizure free, a larger virtual resection made five virtually seizure free. We also examined 10 medically refractory focal epilepsy patients implanted with the responsive neurostimulator system and virtually targeted the responsive neurostimulator system stimulation contacts proximal to sites generating FR at highest rates to determine if the simulated value of the stimulated seizure-onset zone and stimulated FR metrics would trend towards those patients with a better seizure outcome. Our results suggest the following: (i) FR measures can accurately predict whether a resection, defined by the standard of care, will result in seizure freedom; (ii) utilizing FR alone for planning an efficacious surgery can be associated with larger resections; (iii) when FR metrics predict the standard-of-care resection will fail, amending the boundaries of the planned resection with certain FR-generating sites may improve outcome and (iv) more work is required to determine whether targeting responsive neurostimulator system stimulation contact proximal to FR generating sites will improve seizure outcome.

Published

2024

6. Successful harmonization in EpiBioS4Rx biomarker study on post-traumatic epilepsy paves the way towards powered preclinical multicenter studies

Author

Ndode-Ekane, Xavier Ekolle, Ali, Idrish, Santana-Gomez, Cesar E, Casillas-Espinosa, Pablo M, Andrade, Pedro, Smith, Gregory, Paananen, Tomi, Manninen, Eppu, Immonen, Riikka, Puhakka, Noora, Ciszek, Robert, Hämäläinen, Elina, Brady, Rhys D, Silva, Juliana, Braine, Emma, Hudson, Matthew R, Yamakawa, Glenn, Jones, Nigel C, Shultz, Sandy R, Wright, David, Harris, Neil, Gröhn, Olli, Staba, Richard J, O'Brien, Terence J, and Pitkänen, Asla

Subjects

Biomedical and Clinical Sciences, Neurosciences, Neurodegenerative, Physical Injury - Accidents and Adverse Effects, Brain Disorders, Traumatic Head and Spine Injury, Traumatic Brain Injury (TBI), Epilepsy, Good Health and Well Being, Animals, Rats, Biomarkers, Brain Injuries, Traumatic, Disease Models, Animal, Epilepsy, Post-Traumatic, Seizures, Multicenter Studies as Topic, Common data element, Epileptogenesis, Lateral fluid -percussion injury, Magnetic, Resonance imaging, Plasma sampling, Traumatic brain injury, Videoelectroencephalogram, Lateral fluid-percussion injury, Neurology & Neurosurgery

Abstract

ObjectiveProject 1 of the Preclinical Multicenter Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) consortium aims to identify preclinical biomarkers for antiepileptogenic therapies following traumatic brain injury (TBI). The international participating centers in Finland, Australia, and the United States have made a concerted effort to ensure protocol harmonization. Here, we evaluate the success of harmonization process by assessing the timing, coverage, and performance between the study sites.MethodWe collected data on animal housing conditions, lateral fluid-percussion injury model production, postoperative care, mortality, post-TBI physiological monitoring, timing of blood sampling and quality, MR imaging timing and protocols, and duration of video-electroencephalography (EEG) follow-up using common data elements. Learning effect in harmonization was assessed by comparing procedural accuracy between the early and late stages of the project.ResultsThe animal housing conditions were comparable between the study sites but the postoperative care procedures varied. Impact pressure, duration of apnea, righting reflex, and acute mortality differed between the study sites (p  0.05). Plasma quality was poor in 4% of the samples in UEF, 1% in Monash and 14% in UCLA. More than 97% of the final cohort were MR imaged at all timepoints in all study sites. The timing of imaging did not differ on D2 and D9 (p > 0.05), but varied at D30, 5 months, and ex vivo timepoints (p  0.05). A decrease in acute mortality and increase in plasma quality across time reflected a learning effect in the TBI production and blood sampling protocols.SignificanceOur study is the first demonstration of the feasibility of protocol harmonization for performing powered preclinical multi-center trials for biomarker and therapy discovery of post-traumatic epilepsy.

Published

2024

7. Optimizing detection and deep learning-based classification of pathological high-frequency oscillations in epilepsy.

Author

Monsoor, Tonmoy, Zhang, Yipeng, Daida, Atsuro, Oana, Shingo, Lu, Qiujing, Hussain, Shaun, Fallah, Aria, Sankar, Raman, Speier, William, Staba, Richard, Roychowdhury, Vwani, and Nariai, Hiroki

Subjects

Deep learning, HFO, MNI, Machine learning, STE, Child, Humans, Deep Learning, Epilepsy, Seizures, Electroencephalography, Drug Resistant Epilepsy

Abstract

OBJECTIVE: This study aimed to explore sensitive detection methods for pathological high-frequency oscillations (HFOs) to improve seizure outcomes in epilepsy surgery. METHODS: We analyzed interictal HFOs (80-500 Hz) in 15 children with medication-resistant focal epilepsy who underwent chronic intracranial electroencephalogram via subdural grids. The HFOs were assessed using the short-term energy (STE) and Montreal Neurological Institute (MNI) detectors and examined for spike association and time-frequency plot characteristics. A deep learning (DL)-based classification was applied to purify pathological HFOs. Postoperative seizure outcomes were correlated with HFO-resection ratios to determine the optimal HFO detection method. RESULTS: The MNI detector identified a higher percentage of pathological HFOs than the STE detector, but some pathological HFOs were detected only by the STE detector. HFOs detected by both detectors had the highest spike association rate. The Union detector, which detects HFOs identified by either the MNI or STE detector, outperformed other detectors in predicting postoperative seizure outcomes using HFO-resection ratios before and after DL-based purification. CONCLUSIONS: HFOs detected by standard automated detectors displayed different signal and morphological characteristics. DL-based classification effectively purified pathological HFOs. SIGNIFICANCE: Enhancing the detection and classification methods of HFOs will improve their utility in predicting postoperative seizure outcomes.

Published

2023

8. Image data harmonization tools for the analysis of post-traumatic epilepsy development in preclinical multisite MRI studies.

Author

Bhagavatula, Sweta, Cabeen, Ryan, Harris, Neil, Gröhn, Olli, Wright, David, Garner, Rachael, Bennett, Alexis, Alba, Celina, Martinez, Aubrey, Ndode-Ekane, Xavier, Andrade, Pedro, Paananen, Tomi, Ciszek, Robert, Immonen, Riikka, Manninen, Eppu, Puhakka, Noora, Tohka, Jussi, Heiskanen, Mette, Ali, Idrish, Shultz, Sandy, Casillas-Espinosa, Pablo, Yamakawa, Glenn, Jones, Nigel, Hudson, Matthew, Silva, Juliana, Braine, Emma, Brady, Rhys, Santana-Gomez, Cesar, Smith, Gregory, Staba, Richard, OBrien, Terence, Pitkänen, Asla, and Duncan, Dominique

Subjects

Epilepsy, MRI, Neuroimaging, Preclinical research, Rat model, TBI, Animals, Epilepsy, Post-Traumatic, Diffusion Tensor Imaging, Magnetic Resonance Imaging, Epilepsy, Biomarkers, Brain

Abstract

Preclinical MRI studies have been utilized for the discovery of biomarkers that predict post-traumatic epilepsy (PTE). However, these single site studies often lack statistical power due to limited and homogeneous datasets. Therefore, multisite studies, such as the Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx), are developed to create large, heterogeneous datasets that can lead to more statistically significant results. EpiBioS4Rx collects preclinical data internationally across sites, including the United States, Finland, and Australia. However, in doing so, there are robust normalization and harmonization processes that are required to obtain statistically significant and generalizable results. This work describes the tools and procedures used to harmonize multisite, multimodal preclinical imaging data acquired by EpiBioS4Rx. There were four main harmonization processes that were utilized, including file format harmonization, naming convention harmonization, image coordinate system harmonization, and diffusion tensor imaging (DTI) metrics harmonization. By using Python tools and bash scripts, the file formats, file names, and image coordinate systems are harmonized across all the sites. To harmonize DTI metrics, values are estimated for each voxel in an image to generate a histogram representing the whole image. Then, the Quantitative Imaging Toolkit (QIT) modules are utilized to scale the mode to a value of one and depict the subsequent harmonized histogram. The standardization of file formats, naming conventions, coordinate systems, and DTI metrics are qualitatively assessed. The histograms of the DTI metrics were generated for all the individual rodents per site. For inter-site analysis, an average of the individual scans was calculated to create a histogram that represents each site. In order to ensure the analysis can be run at the level of individual animals, the sham and TBI cohort were analyzed separately, which depicted the same harmonization factor. The results demonstrate that these processes qualitatively standardize the file formats, naming conventions, coordinate systems, and DTI metrics of the data. This assists in the ability to share data across the study, as well as disseminate tools that can help other researchers to strengthen the statistical power of their studies and analyze data more cohesively.

Published

2023

9. Early preclinical plasma protein biomarkers of brain trauma are influenced by early seizures and levetiracetam.

Author

Saletti, Patricia G, Mowrey, Wenzhu B, Liu, Wei, Li, Qianyun, McCullough, Jesse, Aniceto, Roxanne, Lin, I-Hsuan, Eklund, Michael, Casillas-Espinosa, Pablo M, Ali, Idrish, Santana-Gomez, Cesar, Coles, Lisa, Shultz, Sandy R, Jones, Nigel, Staba, Richard, O'Brien, Terence J, Moshé, Solomon L, Agoston, Denes V, Galanopoulou, Aristea S, and EpiBioS4Rx Study Group

Subjects

EpiBioS4Rx Study Group, Animals, Rats, Rats, Sprague-Dawley, Seizures, Blood Proteins, HMGB1 Protein, Male, Biomarkers, Brain Injuries, Traumatic, Levetiracetam, inflammation, lateral fluid percussion injury, levetiracetam, neuromotor recovery, tau, traumatic brain injury, Brain Disorders, Neurosciences, Traumatic Head and Spine Injury, Epilepsy, Neurodegenerative, Physical Injury - Accidents and Adverse Effects, Traumatic Brain Injury (TBI)

Abstract

ObjectiveWe used the lateral fluid percussion injury (LFPI) model of moderate-to-severe traumatic brain injury (TBI) to identify early plasma biomarkers predicting injury, early post-traumatic seizures or neuromotor functional recovery (neuroscores), considering the effect of levetiracetam, which is commonly given after severe TBI.MethodsAdult male Sprague-Dawley rats underwent left parietal LFPI, received levetiracetam (200 mg/kg bolus, 200 mg/kg/day subcutaneously for 7 days [7d]) or vehicle post-LFPI, and were continuously video-EEG recorded (n = 14/group). Sham (craniotomy only, n = 6), and naïve controls (n = 10) were also used. Neuroscores and plasma collection were done at 2d or 7d post-LFPI or equivalent timepoints in sham/naïve. Plasma protein biomarker levels were determined by reverse phase protein microarray and classified according to injury severity (LFPI vs. sham/control), levetiracetam treatment, early seizures, and 2d-to-7d neuroscore recovery, using machine learning.ResultsLow 2d plasma levels of Thr231 -phosphorylated tau protein (pTAU-Thr231 ) and S100B combined (ROC AUC = 0.7790) predicted prior craniotomy surgery (diagnostic biomarker). Levetiracetam-treated LFPI rats were differentiated from vehicle treated by the 2d-HMGB1, 2d-pTAU-Thr231 , and 2d-UCHL1 plasma levels combined (ROC AUC = 0.9394) (pharmacodynamic biomarker). Levetiracetam prevented the seizure effects on two biomarkers that predicted early seizures only among vehicle-treated LFPI rats: pTAU-Thr231 (ROC AUC = 1) and UCHL1 (ROC AUC = 0.8333) (prognostic biomarker of early seizures among vehicle-treated LFPI rats). Levetiracetam-resistant early seizures were predicted by high 2d-IFNγ plasma levels (ROC AUC = 0.8750) (response biomarker). 2d-to-7d neuroscore recovery was best predicted by higher 2d-S100B, lower 2d-HMGB1, and 2d-to-7d increase in HMGB1 or decrease in TNF (P

Published

2023

10. Graph theoretical measures of fast ripple networks improve the accuracy of post-operative seizure outcome prediction.

Author

Weiss, Shennan, Fried, Itzhak, Wu, Chengyuan, Sharan, Ashwini, Rubinstein, Daniel, Sperling, Michael, Staba, Richard, and Engel, Jerome

Subjects

Humans, Margins of Excision, Seizures, Brain, Prognosis, Magnetic Resonance Imaging, Electroencephalography

Abstract

Fast ripples (FR) are a biomarker of epileptogenic brain, but when larger portions of FR generating regions are resected seizure freedom is not always achieved. To evaluate and improve the diagnostic accuracy of FR resection for predicting seizure freedom we compared the FR resection ratio (RR) with FR network graph theoretical measures. In 23 patients FR were semi-automatically detected and quantified in stereo EEG recordings during sleep. MRI normalization and co-registration localized contacts and relation to resection margins. The number of FR, and graph theoretical measures, which were spatial (i.e., FR rate-distance radius) or temporal correlational (i.e., FR mutual information), were compared with the resection margins and with seizure outcome We found that the FR RR did not correlate with seizure-outcome (p > 0.05). In contrast, the FR rate-distance radius resected difference and the FR MI mean characteristic path length RR did correlate with seizure-outcome (p

Published

2023

11. High-rate leading spikes in propagating spike sequences predict seizure outcome in surgical patients with temporal lobe epilepsy.

Author

Shamas, Mohamad, Yeh, Hsiang, Fried, Itzhak, Engel, Jerome, and Staba, Richard

Subjects

intracranial electroencephalography, seizure recurrence, spike coupling, spike rate, temporal lobe

Abstract

Inter-ictal spikes aid in the diagnosis of epilepsy and in planning surgery of medication-resistant epilepsy. However, the localizing information from spikes can be unreliable because spikes can propagate, and the burden of spikes, often assessed as a rate, does not always correlate with the seizure onset zone or seizure outcome. Recent work indicates identifying where spikes regularly emerge and spread could localize the seizure network. Thus, the current study sought to better understand where and how rates of single and coupled spikes, and especially brain regions with high-rate and leading spike of a propagating sequence, informs the extent of the seizure network. In 37 patients with medication-resistant temporal lobe seizures, who had surgery to treat their seizure disorder, an algorithm detected spikes in the pre-surgical depth inter-ictal EEG. A separate algorithm detected spike propagation sequences and identified the location of leading and downstream spikes in each sequence. We analysed the rate and power of single spikes on each electrode and coupled spikes between pairs of electrodes, and the proportion of sites with high-rate, leading spikes in relation to the seizure onset zone of patients seizure free (n = 19) and those with continuing seizures (n = 18). We found increased rates of single spikes in mesial temporal seizure onset zone (ANOVA, P < 0.001, η2 = 0.138), and increased rates of coupled spikes within, but not between, mesial-, lateral- and extra-temporal seizure onset zone of patients with continuing seizures (P < 0.001; η2 = 0.195, 0.113 and 0.102, respectively). In these same patients, there was a higher proportion of brain regions with high-rate leaders, and each sequence contained a greater number of spikes that propagated with a higher efficiency over a longer distance outside the seizure onset zone than patients seizure free (Wilcoxon, P = 0.0172). The proportion of high-rate leaders in and outside the seizure onset zone could predict seizure outcome with area under curve = 0.699, but not rates of single or coupled spikes (0.514 and 0.566). Rates of coupled spikes to a greater extent than single spikes localize the seizure onset zone and provide evidence for inter-ictal functional segregation, which could be an adaptation to avert seizures. Spike rates, however, have little value in predicting seizure outcome. High-rate spike sites leading propagation could represent sources of spikes that are important components of an efficient seizure network beyond the clinical seizure onset zone, and like the seizure onset zone these, too, need to be removed, disconnected or stimulated to increase the likelihood for seizure control.

Published

2023

12. Fast ripples reflect increased excitability that primes epileptiform spikes.

Author

Weiss, Shennan, Fried, Itzhak, Engel, Jerome, Sperling, Michael, Wong, Robert, Nir, Yuval, and Staba, Richard

Subjects

epileptiform spike, fast ripple, high-frequency oscillation, neuron, ripple

Abstract

The neuronal circuit disturbances that drive inter-ictal and ictal epileptiform discharges remain elusive. Using a combination of extra-operative macro-electrode and micro-electrode inter-ictal recordings in six pre-surgical patients during non-rapid eye movement sleep, we found that, exclusively in the seizure onset zone, fast ripples (200-600 Hz), but not ripples (80-200 Hz), frequently occur

Published

2023

13. Characterizing physiological high-frequency oscillations using deep learning

Author

Zhang, Yipeng, Chung, Hoyoung, Ngo, Jacquline P, Monsoor, Tonmoy, Hussain, Shaun A, Matsumoto, Joyce H, Walshaw, Patricia D, Fallah, Aria, Sim, Myung Shin, Asano, Eishi, Sankar, Raman, Staba, Richard J, Engel, Jerome, Speier, William, Roychowdhury, Vwani, and Nariai, Hiroki

Subjects

Engineering, Biomedical and Clinical Sciences, Neurosciences, Biomedical Engineering, Brain Disorders, Neurodegenerative, Machine Learning and Artificial Intelligence, Neurological, Child, Humans, Electroencephalography, Deep Learning, Epilepsy, Seizures, Brain, HFO, physiological HFO, machine learning, Clinical Sciences, Biomedical engineering

Abstract

Objective.Intracranially-recorded interictal high-frequency oscillations (HFOs) have been proposed as a promising spatial biomarker of the epileptogenic zone. However, HFOs can also be recorded in the healthy brain regions, which complicates the interpretation of HFOs. The present study aimed to characterize salient features of physiological HFOs using deep learning (DL).Approach.We studied children with neocortical epilepsy who underwent intracranial strip/grid evaluation. Time-series EEG data were transformed into DL training inputs. The eloquent cortex (EC) was defined by functional cortical mapping and used as a DL label. Morphological characteristics of HFOs obtained from EC (ecHFOs) were distilled and interpreted through a novel weakly supervised DL model.Main results.A total of 63 379 interictal intracranially-recorded HFOs from 18 children were analyzed. The ecHFOs had lower amplitude throughout the 80-500 Hz frequency band around the HFO onset and also had a lower signal amplitude in the low frequency band throughout a one-second time window than non-ecHFOs, resembling a bell-shaped template in the time-frequency map. A minority of ecHFOs were HFOs with spikes (22.9%). Such morphological characteristics were confirmed to influence DL model prediction via perturbation analyses. Using the resection ratio (removed HFOs/detected HFOs) of non-ecHFOs, the prediction of postoperative seizure outcomes improved compared to using uncorrected HFOs (area under the ROC curve of 0.82, increased from 0.76).Significance.We characterized salient features of physiological HFOs using a DL algorithm. Our results suggested that this DL-based HFO classification, once trained, might help separate physiological from pathological HFOs, and efficiently guide surgical resection using HFOs.

Published

2022

14. Interictal Gamma Event Connectivity Differentiates the Seizure Network and Outcome in Patients after Temporal Lobe Epilepsy Surgery

Author

Shamas, Mohamad, Yeh, Hsiang J, Fried, Itzhak, Engel, Jerome, and Staba, Richard

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Psychology, Epilepsy, Brain Disorders, Clinical Research, Neurosciences, Neurodegenerative, 2.1 Biological and endogenous factors, Aetiology, Neurological, Humans, Epilepsy, Temporal Lobe, Seizures, Brain, Temporal Lobe, Electroencephalography, epileptic network, event connectivity, intracerebral recordings, seizure onset zone

Abstract

Studies of interictal EEG functional connectivity in the epileptic brain seek to identify abnormal interactions between brain regions involved in generating seizures, which clinically often is defined by the seizure onset zone (SOZ). However, there is evidence for abnormal connectivity outside the SOZ (NSOZ), and removal of the SOZ does not always result in seizure control, suggesting, in some cases, that the extent of abnormal connectivity indicates a larger seizure network than the SOZ. To better understand the potential differences in interictal functional connectivity in relation to the seizure network and outcome, we computed event connectivity in the theta (4-8 Hz, ThEC), low-gamma (30-55 Hz, LGEC), and high-gamma (65-95 Hz, HGEC) bands from interictal depth EEG recorded in surgical patients with medication-resistant seizures suspected to begin in the temporal lobe. Analysis finds stronger LGEC and HGEC in SOZ than NSOZ of seizure-free (SF) patients (p = 1.10e-9, 0.0217), but no difference in not seizure-free (NSF) patients. There were stronger LGEC and HGEC between mesial and lateral temporal SOZ of SF than NSF patients (p = 0.00114, 0.00205), and stronger LGEC and ThEC in NSOZ of NSF than SF patients (p = 0.0089, 0.0111). These results show that event connectivity is sensitive to differences in the interactions between regions in SOZ and NSOZ and SF and NSF patients. Patients with differential strengths in event connectivity could represent a well-localized seizure network, whereas an absence of differences could indicate a larger seizure network than the one localized by the SOZ and higher likelihood for seizure recurrence.

Published

2022

15. Drug-resistant epilepsy and the hypothesis of intrinsic severity: What about the high-frequency oscillations?

Author

Santana-Gomez, Cesar E, Engel, Jerome, and Staba, Richard

Subjects

Animals, Epilepsy, Seizures, Electroencephalography, Brain Waves, Drug Resistant Epilepsy, EEG, drug-resistant epilepsy, epilepsy, epilepsy severity, Neurodegenerative, Antimicrobial Resistance, Brain Disorders, Neurosciences, Clinical Research, 2.1 Biological and endogenous factors, Aetiology, Neurological

Abstract

Drug-resistant epilepsy (DRE) affects approximately one-third of the patients with epilepsy. Based on experimental findings from animal models and brain tissue from patients with DRE, different hypotheses have been proposed to explain the cause(s) of drug resistance. One is the intrinsic severity hypothesis that posits that drug resistance is an inherent property of epilepsy related to disease severity. Seizure frequency is one measure of epilepsy severity, but frequency alone is an incomplete measure of severity and does not fully explain basic research and clinical studies on drug resistance; thus, other measures of epilepsy severity are needed. One such measure could be pathological high-frequency oscillations (HFOs), which are believed to reflect the neuronal disturbances responsible for the development of epilepsy and the generation of spontaneous seizures. In this manuscript, we will briefly review the intrinsic severity hypothesis, describe basic and clinical research on HFOs in the epileptic brain, and based on this evidence discuss whether HFOs could be a clinical measure of epilepsy severity. Understanding the mechanisms of DRE is critical for producing breakthroughs in the development and testing of novel strategies for treatment.

Published

2022

16. Susceptibility to epilepsy after traumatic brain injury is associated with preexistent gut microbiome profile

Author

Medel‐Matus, Jesus‐Servando, Lagishetty, Venu, Santana‐Gomez, Cesar, Shin, Don, Mowrey, Wenzhu, Staba, Richard J, Galanopoulou, Aristea S, Sankar, Raman, Jacobs, Jonathan P, and Mazarati, Andrey M

Subjects

Brain Disorders, Prevention, Animals, Brain Injuries, Traumatic, Epilepsy, Epilepsy, Post-Traumatic, Fatty Acids, Volatile, Gastrointestinal Microbiome, Humans, Rats, Rats, Sprague-Dawley, fluid percussion injury, microbiota, posttraumatic epilepsy, random forest classifier, short-chain fatty acids, Clinical Sciences, Neurosciences, Neurology & Neurosurgery

Abstract

ObjectiveWe examined whether posttraumatic epilepsy (PTE) is associated with measurable perturbations in gut microbiome.MethodsAdult Sprague Dawley rats were subjected to lateral fluid percussion injury (LFPI). PTE was examined 7 months after LFPI, during 4-week continuous video-electroencephalographic monitoring. 16S ribosomal RNA gene sequencing was performed in fecal samples collected before LFPI/sham-LFPI and 1 week, 1 month, and 7 months thereafter. Longitudinal analyses of alpha diversity, beta diversity, and differential microbial abundance were performed. Short-chain fatty acids (SCFAs) were measured in fecal samples collected before LFPI by liquid chromatography with tandem mass spectrometry.ResultsAlpha diversity changed over time in both LFPI and sham-LFPI subjects; no association was observed between alpha diversity and LFPI, the severity of post-LFPI neuromotor impairments, and PTE. LFPI produced significant changes in beta diversity and selective changes in microbial abundances associated with the severity of neuromotor impairments. No association between LFPI-dependent microbial perturbations and PTE was detected. PTE was associated with beta diversity irrespective of timepoint vis-à-vis LFPI, including at baseline. Preexistent fecal microbial abundances of four amplicon sequence variants belonging to the Lachnospiraceae family (three enriched and one depleted) predicted the risk of PTE, with area under the curve (AUC) of .73. Global SCFA content was associated with the increased risk of PTE, with AUC of .722, and with 2-methylbutyric (depleted), valeric (depleted), isobutyric (enriched), and isovaleric (enriched) acids being the most important factors (AUC = .717). When the analyses of baseline microbial and SCFA compositions were combined, AUC to predict PTE increased to .78.SignificanceWhereas LFPI produces no perturbations in the gut microbiome that are associated with PTE, the risk of PTE can be stratified based on preexistent microbial abundances and SCFA content.

Published

2022

17. Graph theoretical measures of fast ripples support the epileptic network hypothesis

Author

Weiss, Shennan A, Pastore, Tomas, Orosz, Iren, Rubinstein, Daniel, Gorniak, Richard, Waldman, Zachary, Fried, Itzhak, Wu, Chengyuan, Sharan, Ashwini, Slezak, Diego, Worrell, Gregory, Engel, Jerome, Sperling, Michael R, and Staba, Richard J

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Brain Disorders, Neurodegenerative, Epilepsy, epilepsy surgery, high-frequency oscillation, fast ripple, brain network, Clinical sciences, Biological psychology

Abstract

The epileptic network hypothesis and epileptogenic zone hypothesis are two theories of ictogenesis. The network hypothesis posits that coordinated activity among interconnected nodes produces seizures. The epileptogenic zone hypothesis posits that distinct regions are necessary and sufficient for seizure generation. High-frequency oscillations, and particularly fast ripples, are thought to be biomarkers of the epileptogenic zone. We sought to test these theories by comparing high-frequency oscillation rates and networks in surgical responders and non-responders, with no appreciable change in seizure frequency or severity, within a retrospective cohort of 48 patients implanted with stereo-EEG electrodes. We recorded inter-ictal activity during non-rapid eye movement sleep and semi-automatically detected and quantified high-frequency oscillations. Each electrode contact was localized in normalized coordinates. We found that the accuracy of seizure onset zone electrode contact classification using high-frequency oscillation rates was not significantly different in surgical responders and non-responders, suggesting that in non-responders the epileptogenic zone partially encompassed the seizure onset zone(s) (P > 0.05). We also found that in the responders, fast ripple on oscillations exhibited a higher spectral content in the seizure onset zone compared with the non-seizure onset zone (P 350 Hz. The first was a rate-distance network that multiplied the Euclidian distance between fast ripple-generating contacts by the average rate of fast ripple in the two contacts. The radius of the rate-distance network, which excluded seizure onset zone nodes, discriminated non-responders, including patients not offered resection or responsive neurostimulation due to diffuse multifocal onsets, with an accuracy of 0.77 [95% confidence interval (CI) 0.56-0.98]. The second fast ripple network was constructed using the mutual information between the timing of the events to measure functional connectivity. For most non-responders, this network had a longer characteristic path length, lower mean local efficiency in the non-seizure onset zone, and a higher nodal strength among non-seizure onset zone nodes relative to seizure onset zone nodes. The graphical theoretical measures from the rate-distance and mutual information networks of 22 non- responsive neurostimulation treated patients was used to train a support vector machine, which when tested on 13 distinct patients classified non-responders with an accuracy of 0.92 (95% CI 0.75-1). These results indicate patients who do not respond to surgery or those not selected for resection or responsive neurostimulation can be explained by the epileptic network hypothesis that is a decentralized network consisting of widely distributed, hyperexcitable fast ripple-generating nodes.

Published

2022

18. Refining epileptogenic high-frequency oscillations using deep learning: a reverse engineering approach

Author

Zhang, Yipeng, Lu, Qiujing, Monsoor, Tonmoy, Hussain, Shaun A, Qiao, Joe X, Salamon, Noriko, Fallah, Aria, Sim, Myung Shin, Asano, Eishi, Sankar, Raman, Staba, Richard J, Engel, Jerome, Speier, William, Roychowdhury, Vwani, and Nariai, Hiroki

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Neurodegenerative, Brain Disorders, Networking and Information Technology R&D (NITRD), Machine Learning and Artificial Intelligence, Epilepsy, Bioengineering, HFO, physiological HFO, pathological HFO, artificial intelligence, machine learning, Clinical sciences, Biological psychology

Abstract

Intracranially recorded interictal high-frequency oscillations have been proposed as a promising spatial biomarker of the epileptogenic zone. However, its visual verification is time-consuming and exhibits poor inter-rater reliability. Furthermore, no method is currently available to distinguish high-frequency oscillations generated from the epileptogenic zone (epileptogenic high-frequency oscillations) from those generated from other areas (non-epileptogenic high-frequency oscillations). To address these issues, we constructed a deep learning-based algorithm using chronic intracranial EEG data via subdural grids from 19 children with medication-resistant neocortical epilepsy to: (i) replicate human expert annotation of artefacts and high-frequency oscillations with or without spikes, and (ii) discover epileptogenic high-frequency oscillations by designing a novel weakly supervised model. The 'purification power' of deep learning is then used to automatically relabel the high-frequency oscillations to distill epileptogenic high-frequency oscillations. Using 12 958 annotated high-frequency oscillation events from 19 patients, the model achieved 96.3% accuracy on artefact detection (F1 score = 96.8%) and 86.5% accuracy on classifying high-frequency oscillations with or without spikes (F1 score = 80.8%) using patient-wise cross-validation. Based on the algorithm trained from 84 602 high-frequency oscillation events from nine patients who achieved seizure-freedom after resection, the majority of such discovered epileptogenic high-frequency oscillations were found to be ones with spikes (78.6%, P

Published

2022

19. The Role of High-Frequency Oscillation Networks in Managing Pharmacoresistant Epilepsy

Author

Weiss, Shennan Aibel, Staba, Richard J., Rocha, Luisa L., editor, Lazarowski, Alberto, editor, and Cavalheiro, Esper A., editor

Published

2023

20. Accuracy of high-frequency oscillations recorded intraoperatively for classification of epileptogenic regions

Author

Weiss, Shennan A, Staba, Richard J, Sharan, Ashwini, Wu, Chengyuan, Rubinstein, Daniel, Das, Sandhitsu, Waldman, Zachary, Orosz, Iren, Worrell, Gregory, Engel, Jerome, and Sperling, Michael R

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Clinical Research, Neurosciences, Brain Disorders, Sleep Research, Electrocorticography, Electrodes, Epilepsy, Female, Humans, Intraoperative Neurophysiological Monitoring, Male, Seizures, Sleep

Abstract

To see whether acute intraoperative recordings using stereo EEG (SEEG) electrodes can replace prolonged interictal intracranial EEG (iEEG) recording, making the process more efficient and safer, 10 min of iEEG were recorded following electrode implantation in 16 anesthetized patients, and 1-2 days later during non-rapid eye movement (REM) sleep. Ripples on oscillations (RonO, 80-250 Hz), ripples on spikes (RonS), sharp-spikes, fast RonO (fRonO, 250-600 Hz), and fast RonS (fRonS) were semi-automatically detected. HFO power and frequency were compared between the conditions using a generalized linear mixed-effects model. HFO rates were compared using a two-way repeated measures ANOVA with anesthesia type and SOZ as factors. A receiver-operating characteristic (ROC) curve analysis quantified seizure onset zone (SOZ) classification accuracy, and the scalar product was used to assess spatial reliability. Resection of contacts with the highest rate of events was compared with outcome. During sleep, all HFOs, except fRonO, were larger in amplitude compared to intraoperatively (p

Published

2021

21. Scalp EEG interictal high frequency oscillations as an objective biomarker of infantile spasms

Author

Nariai, Hiroki, Hussain, Shaun A, Bernardo, Danilo, Motoi, Hirotaka, Sonoda, Masaki, Kuroda, Naoto, Asano, Eishi, Nguyen, Jimmy C, Elashoff, David, Sankar, Raman, Bragin, Anatol, Staba, Richard J, and Wu, Joyce Y

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Clinical Research, Neurodegenerative, Neurosciences, Brain, Brain Mapping, Brain Waves, Electroencephalography, Female, Humans, Infant, Male, Retrospective Studies, Scalp, Spasms, Infantile, HFO, FR, Ripple, Physiological HFO, Modulation index, Engineering, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo investigate the diagnostic utility of high frequency oscillations (HFOs) via scalp electroencephalogram (EEG) in infantile spasms.MethodsWe retrospectively analyzed interictal slow-wave sleep EEGs sampled at 2,000 Hz recorded from 30 consecutive patients who were suspected of having infantile spasms. We measured the rate of HFOs (80-500 Hz) and the strength of the cross-frequency coupling between HFOs and slow-wave activity (SWA) at 3-4 Hz and 0.5-1 Hz as quantified with modulation indices (MIs).ResultsTwenty-three patients (77%) exhibited active spasms during the overnight EEG recording. Although the HFOs were detected in all children, increased HFO rate and MIs correlated with the presence of active spasms (p

Published

2020

22. Emerging roles of network analysis for epilepsy

Author

Stacey, William, Kramer, Mark, Gunnarsdottir, Kristin, Gonzalez-Martinez, Jorge, Zaghloul, Kareem, Inati, Sara, Sarma, Sridevi, Stiso, Jennifer, Khambhati, Ankit N, Bassett, Danielle S, Smith, Rachel J, Liu, Virginia B, Lopour, Beth A, and Staba, Richard

Subjects

Biomedical and Clinical Sciences, Neurosciences, Epilepsy, Brain Disorders, Neurodegenerative, Neurological, Brain, Brain Mapping, Electroencephalography, Humans, Nerve Net, EEG, Network analysis, Functional connectivity, Graph theory, Control theory, Infantile spasms, Neurology & Neurosurgery

Abstract

In recent years there has been increasing interest in applying network science tools to EEG data. At the 2018 American Epilepsy Society conference in New Orleans, LA, the yearly session of the Engineering and Neurostimulation Special Interest Group focused on emerging, translational technologies to analyze seizure networks. Each speaker demonstrated practical examples of how network tools can be utilized in clinical care and provide additional data to help care for patients with intractable epilepsy. The groups presented advances using tools from functional connectivity, control theory, and graph theory to analyze human EEG data. These tools have great potential to augment clinical interpretation of EEG signals.

Published

2020

23. Ripples Have Distinct Spectral Properties and Phase-Amplitude Coupling With Slow Waves, but Indistinct Unit Firing, in Human Epileptogenic Hippocampus

Author

Weiss, Shennan A, Song, Inkyung, Leng, Mei, Pastore, Tomás, Slezak, Diego, Waldman, Zachary, Orosz, Iren, Gorniak, Richard, Donmez, Mustafa, Sharan, Ashwini, Wu, Chengyuan, Fried, Itzhak, Sperling, Michael R, Bragin, Anatol, Engel, Jerome, Nir, Yuval, and Staba, Richard

Subjects

Biomedical and Clinical Sciences, Neurosciences, Sleep Research, Neurodegenerative, Brain Disorders, Basic Behavioral and Social Science, Behavioral and Social Science, Neurological, sleep, high-frequency oscillation, slow wave, epilepsy, hippocampus, ripple, fast ripple, Clinical Sciences, Psychology, Clinical sciences, Biological psychology

Abstract

Ripple oscillations (80-200 Hz) in the normal hippocampus are involved in memory consolidation during rest and sleep. In the epileptic brain, increased ripple and fast ripple (200-600 Hz) rates serve as a biomarker of epileptogenic brain. We report that both ripples and fast ripples exhibit a preferred phase angle of coupling with the trough-peak (or On-Off) state transition of the sleep slow wave in the hippocampal seizure onset zone (SOZ). Ripples on slow waves in the hippocampal SOZ also had a lower power, greater spectral frequency, and shorter duration than those in the non-SOZ. Slow waves in the mesial temporal lobe modulated the baseline firing rate of excitatory neurons, but did not significantly influence the increased firing rate associated with ripples. In summary, pathological ripples and fast ripples occur preferentially during the On-Off state transition of the slow wave in the epileptogenic hippocampus, and ripples do not require the increased recruitment of excitatory neurons.

Published

2020

24. Preface - Practical and theoretical considerations for performing a multi-center preclinical biomarker discovery study of post-traumatic epileptogenesis: lessons learned from the EpiBioS4Rx consortium.

Author

Pitkänen, Asla, OBrien, Terence, and Staba, Richard

Subjects

Biomarker, Case report form, Common data element, Electroencephalogram, Harmonization, Lateral fluid-percussion injury, Magnetic resonance imaging, Plasma, Post-traumatic epilepsy, Preclinical, Traumatic brain injury, Animals, Biomarkers, Biomedical Research, Brain Injuries, Traumatic, Computational Biology, Disease Models, Animal, Epilepsy, Post-Traumatic, Humans

Abstract

The Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) is a NINDS funded Center-Without-Walls international study aimed at preventing epileptogenesis after traumatic brain injury (TBI). One objective of EpiBioS4Rx relates to preclinical biomarker discovery for post-traumatic epilepsy. In order to perform a statistically appropriately powered biomarker discovery study, EpiBioS4Rx has made a rigorous attempt to harmonize the preclinical procedures performed at the three EpiBioS4Rx centers, located in Finland, Australia, and the USA. Moreover, we have also performed a rigorous interim analysis of the success of procedural harmonization, which is reported in this virtual special issue. The analysis included harmonization of the production of animal model, blood sampling, electroencephalogram analyses (seizures, high-frequency oscillations) and magnetic resonance imaging analysis. Based on lessons learned, we propose a 3-stage protocol to facilitate the success of preclinical multicenter studies: preparation ⇨ testing ⇨ multicenter study. The need of funding for preparation and testing phases, which precede the actual multicenter study and are necessary for its success, should be taken into account in the design of funding schemes.

Published

2019

25. Harmonization of pipeline for detection of HFOs in a rat model of post-traumatic epilepsy in preclinical multicenter study on post-traumatic epileptogenesis.

Author

Santana-Gomez, Cesar, Andrade, Pedro, Hudson, Matthew R, Paananen, Tomi, Ciszek, Robert, Smith, Gregory, Ali, Idrish, Rundle, Brian K, Ndode-Ekane, Xavier Ekolle, Casillas-Espinosa, Pablo M, Immonen, Riikka, Puhakka, Noora, Jones, Nigel, Brady, Rhys D, Perucca, Piero, Shultz, Sandy R, Pitkänen, Asla, O'Brien, Terence J, and Staba, Richard

Subjects

Neocortex, Animals, Rats, Sprague-Dawley, Epilepsy, Post-Traumatic, Disease Models, Animal, Percussion, Electrodes, Implanted, Male, Brain Waves, Brain Injuries, Traumatic, Brain oscillation, Common data element, Electroencephalogram, Traumatic brain injury, Brain Disorders, Neurodegenerative, Neurosciences, Physical Injury - Accidents and Adverse Effects, Epilepsy, Traumatic Brain Injury (TBI), Prevention, Traumatic Head and Spine Injury, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

Studies of chronic epilepsy show pathological high frequency oscillations (HFOs) are associated with brain areas capable of generating epileptic seizures. Only a few of these studies have focused on HFOs during the development of epilepsy, but results suggest pathological HFOs could be a biomarker of epileptogenesis. The Epilepsy Bioinformatics Study for Antiepileptogenic Therapy" (EpiBioS4Rx) is a multi-center project designed to identify biomarkers of epileptogenesis after a traumatic brain injury (TBI) and evaluate treatments that could modify or prevent the development of post-traumatic epilepsy. One goal of the EpiBioS4Rx project is to assess whether HFOs could be a biomarker of post-traumatic epileptogenesis. The current study describes the work towards this goal, including the development of common surgical procedures and EEG protocols, an interim analysis of the EEG for HFOs, and identifying issues that need to be addressed for a robust biomarker analysis. At three participating sites - University of Eastern Finland (UEF), Monash University in Melbourne (Melbourne) and University of California, Los Angeles (UCLA) - TBI was induced in adult male Sprague-Dawley rats by lateral fluid-percussion injury. After injury and in sham-operated controls, rats were implanted with screw and microwire electrodes positioned in neocortex and hippocampus to record EEG. A separate group of rats had serial magnetic resonance imaging after injury and then implanted with electrodes at 6 months. Recordings 28 days post-injury were available from UEF and UCLA, but not Melbourne due to technical issues with their EEG files. Analysis of recordings from 4 rats - UEF and UCLA each had one TBI and one sham-operated control - showed EEG contained evidence of HFOs. Computer-automated algorithms detected a total of 1,819 putative HFOs and of these only 40 events (2%) were detected by all three sites. Manual review of all events verified 130 events as HFO and the remainder as false positives. Review of the 40 events detected by all three sites was associated with 88% agreement. This initial report from the EpiBioS4Rx Consortium demonstrates the standardization of EEG electrode placements, recording protocol and long-term EEG monitoring, and differences in detection algorithm HFO results between sites. Additional work on detection strategy, detection algorithm performance, and training in HFO review will be performed to establish a robust, preclinical evaluation of HFOs as a biomarker of post-traumatic epileptogenesis.

Published

2019

26. Harmonization of the pipeline for seizure detection to phenotype post-traumatic epilepsy in a preclinical multicenter study on post-traumatic epileptogenesis.

Author

Casillas-Espinosa, Pablo M, Andrade, Pedro, Santana-Gomez, Cesar, Paananen, Tomi, Smith, Gregory, Ali, Idrish, Ciszek, Robert, Ndode-Ekane, Xavier Ekolle, Brady, Rhys D, Tohka, Jussi, Hudson, Matthew R, Perucca, Piero, Braine, Emma L, Immonen, Riikka, Puhakka, Noora, Shultz, Sandy R, Jones, Nigel C, Staba, Richard J, Pitkänen, Asla, and O'Brien, Terence J

Subjects

Cerebral Cortex, Animals, Rats, Sprague-Dawley, Epilepsy, Post-Traumatic, Seizures, Disease Models, Animal, Phenotype, Video Recording, Male, Biomarkers, Brain Injuries, Traumatic, Common data elements, Electroencephalogram, Post-traumatic epilepsy, Traumatic brain injury, Epilepsy, Neurosciences, Brain Disorders, Neurodegenerative, Physical Injury - Accidents and Adverse Effects, Biotechnology, Traumatic Head and Spine Injury, Traumatic Brain Injury (TBI), Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

RationaleThe Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) Centre without walls is an NIH funded multicenter consortium. One of EpiBioS4Rx projects is a preclinical post-traumatic epileptogenesis biomarker study that involves three study sites: The University of Eastern Finland, Monash University (Melbourne) and the University of California Los Angeles. Our objective is to create a platform for evaluating biomarkers and testing new antiepileptogenic treatments for post-traumatic epilepsy (PTE) using the lateral fluid percussion injury (FPI) model in rats. As only 30-50% of rats with severe lateral FPI develop PTE by 6 months post-injury, prolonged video-EEG monitoring is crucial to identify animals with PTE. Our objective is to harmonize the surgical and data collection procedures, equipment, and data analysis for chronic EEG recording in order to phenotype PTE in this rat model across the three study sites.MethodsTraumatic brain injury (TBI) was induced using lateral FPI in adult male Sprague-Dawley rats aged 11-12 weeks. Animals were divided into two cohorts: a) the long-term video-EEG follow-up cohort (Specific Aim 1), which was implanted with EEG electrodes within 24 h after the injury; and b) the magnetic resonance imaging (MRI) follow-up cohort (Specific Aim 2), at 5 months after lateral FPI. Four cortical epidural screw electrodes (2 ipsilateral, 2 contralateral) and three intracerebral bipolar electrodes were implanted (septal CA1 and the dentate gyrus, layers II and VI of the perilesional cortex both anterior and posterior to the injury site). During the 7th post-TBI month, animals underwent 4 weeks of continuous video-EEG recordings to diagnose of PTE.ResultsAll centers harmonized the induction of TBI and surgical procedures for the implantation of EEG recordings, utilizing 4 or more EEG recording channels to cover areas ipsilateral and contralateral to the brain injury, perilesional cortex and the hippocampus and dentate gyrus. Ground and reference screw electrodes were implanted. At all sites the minimum sampling rate was 512 Hz, utilizing a finite impulse response (FIR) and impedance below 10 KΩ through the entire recording. As part of the quality control criteria we avoided electrical noise, and monitoring changes in impedance over time and the appearance of noise on the recordings. To reduce electrical noise, we regularly checked the integrity of the cables, stability of the EEG recording cap and the appropriate connection of the electrodes with the cables. Following the pipeline presented in this article and after applying the quality control criteria to our EEG recordings all of the sites were successful to phenotype seizure in chronic EEG recordings of animals after TBI.DiscussionDespite differences in video-EEG acquisition equipment used, the three centers were able to consistently phenotype seizures in the lateral fluid-percussion model applying the pipeline presented here. The harmonization of methodology will help to improve the rigor of preclinical research, improving reproducibility of pre-clinical research in the search of biomarkers and therapies to prevent antiepileptogenesis.

Published

2019

27. Unit firing and oscillations at seizure onset in epileptic rodents.

Author

Li, Lin, Bragin, Anatol, Staba, Richard, and Engel, Jerome

Subjects

Brain, Neurons, Animals, Rodentia, Epilepsy, Seizures, Electroencephalography, Brain Waves, Brain Disorders, Neurodegenerative, Neurosciences, 2.1 Biological and endogenous factors, Aetiology, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

Epileptic seizures result from a variety of pathophysiological processes, evidenced by different electrographic ictal onset patterns, as seen on direct brain recordings. The two most common electrographic patterns of focal ictal onset in patients are hypersynchronous (HYP) and low-voltage fast (LVF). Whereas LVF ictal onsets were believed to result from disinhibition; based on similarities with absence seizures, focal HYP ictal onsets were believed to result from increased synchronizing inhibition. Recent findings, however, suggest the differences between these seizure onset types are more complicated and, in some cases, the opposite of these concepts are true. The following review presents evidence that a reduction of tonic inhibition on small pathologically interconnected neuron (PIN) clusters generating pathological high-frequency oscillations (pHFOs), which reflect abnormal synchronously bursting neurons may be the cause of HYP ictal onsets. Increased inhibition preceding LVF ictal onsets are discussed in other reviews in this issue. We postulate that neuronal cell loss following epileptogenic insults can result in structural reorganization, giving rise to small PIN clusters, which generate pHFOs. These clusters have a heterogeneous distribution and are spatially stable over time. Studies have demonstrated that a transient reduction in tonic inhibition causes these clusters to increase in size. This could result in consolidation and synchronization of pHFOs until a critical mass leads to propagation of HYP ictal discharges. Viewed within a network neuroscience framework, local disturbances such as PIN clusters are likely to contribute to large-scale brain network alterations: a better understanding of these epileptogenic networks promises to elucidate mechanisms of ictogenesis, epileptogenesis, and certain comorbidities of epilepsy.

Published

2019

28. Localizing epileptogenic regions using high-frequency oscillations and machine learning.

Author

Weiss, Shennan A, Waldman, Zachary, Raimondo, Federico, Slezak, Diego, Donmez, Mustafa, Worrell, Gregory, Bragin, Anatol, Engel, Jerome, Staba, Richard, and Sperling, Michael

Subjects

Brain, Humans, Epilepsy, Medical Informatics, Biomarkers, Machine Learning, HFO, artificial intelligence, epilepsy, epilepsy surgery, epileptiform spike, fast ripple, high-frequency oscillation, machine learning, phase–amplitude coupling, ripple, seizure, wavelet, Neurodegenerative, Brain Disorders, Neurosciences, Neurological, high frequency oscillation, phase amplitude coupling, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Clinical Sciences, Oncology & Carcinogenesis

Abstract

Pathological high frequency oscillations (HFOs) are putative neurophysiological biomarkers of epileptogenic brain tissue. Utilizing HFOs for epilepsy surgery planning offers the promise of improved seizure outcomes for patients with medically refractory epilepsy. This review discusses possible machine learning strategies that can be applied to HFO biomarkers to better identify epileptogenic regions. We discuss the role of HFO rate, and utilizing features such as explicit HFO properties (spectral content, duration, and power) and phase-amplitude coupling for distinguishing pathological HFO (pHFO) events from physiological HFO events. In addition, the review highlights the importance of neuroanatomical localization in machine learning strategies.

Published

2019

29. Electrophysiological biomarkers of epileptogenicity after traumatic brain injury.

Author

Perucca, Piero, Smith, Gregory, Santana-Gomez, Cesar, Bragin, Anatol, and Staba, Richard

Subjects

Biomarker, EEG, Electrophysiology, Epileptogenesis, High-frequency oscillations, Post-traumatic epilepsy, Repetitive HFOs and spikes, Seizure, Sleep spindles, Traumatic brain injury, Animals, Biomarkers, Brain, Brain Injuries, Traumatic, Brain Waves, Disease Progression, Electrophysiological Phenomena, Epilepsy, Post-Traumatic, Humans, Sleep

Abstract

Post-traumatic epilepsy is the architype of acquired epilepsies, wherein a brain insult initiates an epileptogenic process culminating in an unprovoked seizure after weeks, months or years. Identifying biomarkers of such process is a prerequisite for developing and implementing targeted therapies aimed at preventing the development of epilepsy. Currently, there are no validated electrophysiological biomarkers of post-traumatic epileptogenesis. Experimental EEG studies using the lateral fluid percussion injury model have identified three candidate biomarkers of post-traumatic epileptogenesis: pathological high-frequency oscillations (HFOs, 80-300 Hz); repetitive HFOs and spikes (rHFOSs); and reduction in sleep spindle duration and dominant frequency at the transition from stage III to rapid eye movement sleep. EEG studies in humans have yielded conflicting data; recent evidence suggests that epileptiform abnormalities detected acutely after traumatic brain injury carry a significantly increased risk of subsequent epilepsy. Well-designed studies are required to validate these promising findings, and ultimately establish whether there are post-traumatic electrophysiological features which can guide the development of antiepileptogenic therapies.

Published

2019

30. The epilepsy bioinformatics study for anti-epileptogenic therapy (EpiBioS4Rx) clinical biomarker: Study design and protocol

Author

Vespa, Paul M, Shrestha, Vikesh, Abend, Nicholas, Agoston, Denes, Au, Alicia, Bell, Michael J, Bleck, Thomas P, Blanco, Manuel Buitrago, Claassen, Jan, Diaz-Arrastia, Ramon, Duncan, Dominique, Ellingson, Ben, Foreman, Brandon, Gilmore, Emily J, Hirsch, Lawrence, Hunn, Martin, Kamnaksh, Alaa, McArthur, David, Morokoff, Andrew, O'Brien, Terrence, O'Phelan, Kristine, Robertson, Courtney L, Rosenthal, Eric, Staba, Richard, Toga, Arthur, Willyerd, Frederick A, Zimmermann, Lara, Yam, Elisa, Martinez, Susana, Real, Courtney, and Engel, Jerome

Subjects

Biomedical and Clinical Sciences, Neurosciences, Precision Medicine, Brain Disorders, Traumatic Brain Injury (TBI), Neurodegenerative, Traumatic Head and Spine Injury, Clinical Research, Epilepsy, Physical Injury - Accidents and Adverse Effects, 4.1 Discovery and preclinical testing of markers and technologies, Neurological, Good Health and Well Being, Biomarkers, Brain, Brain Injuries, Traumatic, Computational Biology, Epilepsy, Post-Traumatic, Humans, Longitudinal Studies, Observational Studies as Topic, Prospective Studies, Clinical Sciences, Neurology & Neurosurgery, Biochemistry and cell biology

Abstract

The Epilepsy Bioinformatics Study for Anti-epileptogenic Therapy (EpiBioS4Rx) is a longitudinal prospective observational study funded by the National Institute of Health (NIH) to discover and validate observational biomarkers of epileptogenesis after traumatic brain injury (TBI). A multidisciplinary approach has been incorporated to investigate acute electrical, neuroanatomical, and blood biomarkers after TBI that may predict the development of post-traumatic epilepsy (PTE). We plan to enroll 300 moderate-severe TBI patients with a frontal and/or temporal lobe hemorrhagic contusion. Acute evaluation with blood, imaging and electroencephalographic monitoring will be performed and then patients will be tracked for 2 years to determine the incidence of PTE. Validation of selected biomarkers that are discovered in planned animal models will be a principal feature of this work. Specific hypotheses regarding the discovery of biomarkers have been set forth in this study. An international cohort of 13 centers spanning 2 continents will be developed to facilitate this study, and for future interventional studies.

Published

2019

31. Harmonization of lateral fluid-percussion injury model production and post-injury monitoring in a preclinical multicenter biomarker discovery study on post-traumatic epileptogenesis.

Author

Ndode-Ekane, Xavier Ekolle, Santana-Gomez, Cesar, Casillas-Espinosa, Pablo M, Ali, Idrish, Brady, Rhys D, Smith, Gregory, Andrade, Pedro, Immonen, Riikka, Puhakka, Noora, Hudson, Matthew R, Braine, Emma L, Shultz, Sandy R, Staba, Richard J, O'Brien, Terence J, and Pitkänen, Asla

Subjects

Animals, Humans, Rats, Rats, Sprague-Dawley, Brain Injuries, Epilepsy, Post-Traumatic, Disease Models, Animal, Anticonvulsants, Magnetic Resonance Imaging, Electroencephalography, Statistics, Nonparametric, International Cooperation, Female, Male, Biomarkers, Multicenter study, Post-traumatic epilepsy, Post-traumatic epileptogenesis, Traumatic brain injury, Neurosciences, Physical Injury - Accidents and Adverse Effects, Neurodegenerative, Epilepsy, Traumatic Brain Injury (TBI), Traumatic Head and Spine Injury, Brain Disorders, Good Health and Well Being, Clinical Sciences, Neurology & Neurosurgery

Abstract

Multi-center preclinical studies can facilitate the discovery of biomarkers of antiepileptogenesis and thus facilitate the diagnosis and treatment development of patients at risk of developing post-traumatic epilepsy. However, these studies are often limited by the difficulty in harmonizing experimental protocols between laboratories. Here, we assess whether the production of traumatic brain injury (TBI) using the lateral fluid-percussion injury (FPI) in adult male Sprague-Dawley rats (12 weeks at the time of injury) was harmonized between three laboratories - located in the University of Eastern Finland (UEF), Monash University in Melbourne, Australia (Melbourne) and The University of California, Los Angeles, USA (UCLA). These laboratories are part of the international multicenter-based project, the Epilepsy Bioinformatics Study for Antiepileptogenesis Therapy (EpiBioS4Rx). Lateral FPI was induced in adult male Sprague-Dawley rats. The success of methodological harmonization was assessed by performing inter-site comparison of injury parameters including duration of anesthesia during surgery, impact pressure, post-impact transient apnea, post-impact seizure-like behavior, acute mortality ( Melbourne > UCLA (p

Published

2019

32. Informatics tools to assess the success of procedural harmonization in preclinical multicenter biomarker discovery study on post-traumatic epileptogenesis

Author

Ciszek, Robert, Ndode-Ekane, Xavier Ekolle, Gomez, Cesar Santana, Casillas-Espinosa, Pablo M, Ali, Idrish, Smith, Gregory, Puhakka, Noora, Lapinlampi, Niina, Andrade, Pedro, Kamnaksh, Alaa, Immonen, Riikka, Paananen, Tomi, Hudson, Matthew R, Brady, Rhys D, Shultz, Sandy R, O'Brien, Terence J, Staba, Richard J, Tohka, Jussi, and Pitkänen, Asla

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Algorithms, Animals, Area Under Curve, Biomarkers, Biomedical Research, Brain Injuries, Traumatic, Computational Biology, Electroencephalography, Epilepsy, Follow-Up Studies, Humans, International Cooperation, Male, Rats, Statistics, Nonparametric, Classification, Common data element, Dimensionality reduction, Intraclass correlation, k-nearest neighbor, Lateral fluid-percussion, Machine learning, Traumatic brain injury, Neurology & Neurosurgery

Abstract

The Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) is a National Institutes for Neurological Diseases and Stoke funded Centers-Without-Walls international multidisciplinary study aimed at preventing epileptogenesis. The preclinical biomarker discovery in EpiBios4Rx applies a multicenter study design to allow the number of animals that are required for adequate statistical power for the analysis to be studied in an efficient manner. Further, the use of multiple centers mimics the clinical trial situation, and therefore potentially the chance of successful clinical translation of the outcomes of the study. Its successful implementation requires harmonization of procedures and data analyses between the three contributing centers in Finland, Australia, and USA. The objective of the present analysis was to develop metrics for analysis of the success of harmonization of procedures to guide further data analyses and plan the future multicenter preclinical studies. The interim analysis of data is based on the analysis of data from 212 rats with lateral fluid-percussion injury or sham-operation included in the biomarker discovery by April 30, 2018. The details of protocols, including production of injury, post-injury follow-up, blood sampling, electroencephalogram recording, and magnetic resonance imaging have been presented in the accompanying manuscripts in this Supplement. Implementation of protocols in EpiBios4Rx project participant centers was visualized in 2D using t-distributed stochastic neighborhood embedding (t-SNE). The protocols applied to each rat were presented as feature vectors of procedure related variables (e.g., impact pressure, anesthesia time). The total number of protocol features linked to each rat was 112. The missing data was accounted in visualization by utilizing imputation and adding the number of missing values as a third dimension to 2D t-SNE plot, resulting in a 3D overview of protocol data. Intraclass correlation coefficient (ICC) using Euclidean distances and area under receiver operating characteristic curve (AUC) of k-nearest neighbor classifier (KNN) were utilized to quantify the degree of clustering by center. Both subsets of data with incomplete protocol vectors omitted and missing protocol data imputed were assessed. Our data show that a visible clustering by center was observed in all t-SNE plots, except for day 7 neuroscores. Both ICC and AUC indicated clustering by center in all protocol variable subsets, excluding unimputed day 7 neuroscores (ICC 0.04 and AUC 0.6). ICC for imputed set of all protocol related variables was 0.1 and KNN AUC 0.92. In conclusion, both ICC and AUC indicated differences in protocol between EpiBios4Rx participating centers, which needs to be taken into account in data analysis. Importantly, the majority of observed differences are recoverable as they relate to insufficient updates in record keeping. While AUC score of KNN is a more sensitive measure for protocol harmonization than ICC for data that displays complex splintered clustering, ICC and AUC provide complementary measures to assess the degree of procedural harmonization. This experience should be helpful for other groups planning such multicenter post-traumatic epileptogenesis studies in the future.

Published

2019

33. Harmonization of pipeline for preclinical multicenter MRI biomarker discovery in a rat model of post-traumatic epileptogenesis

Author

Immonen, Riikka, Smith, Gregory, Brady, Rhys D, Wright, David, Johnston, Leigh, Harris, Neil G, Manninen, Eppu, Salo, Raimo, Branch, Craig, Duncan, Dominique, Cabeen, Ryan, Ndode-Ekane, Xavier Ekolle, Gomez, Cesar Santana, Casillas-Espinosa, Pablo M, Ali, Idrish, Shultz, Sandy R, Andrade, Pedro, Puhakka, Noora, Staba, Richard J, O'Brien, Terence J, Toga, Arthur W, Pitkänen, Asla, and Gröhn, Olli

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Brain Disorders, Physical Injury - Accidents and Adverse Effects, Traumatic Head and Spine Injury, Bioengineering, Neurosciences, Prevention, Traumatic Brain Injury (TBI), Biomedical Imaging, Animals, Anisotropy, Brain, Brain Injuries, Traumatic, Disease Models, Animal, Electroencephalography, Epilepsy, Image Processing, Computer-Assisted, Longitudinal Studies, Magnetic Resonance Imaging, Male, Rats, Rats, Sprague-Dawley, Time Factors, Common data element, Diffusion tensor imaging, Magnetization transfer imaging, Multi-site harmonization, Post-traumatic epilepsy, Traumatic brain injury, Neurology & Neurosurgery

Abstract

Preclinical imaging studies of posttraumatic epileptogenesis (PTE) have largely been proof-of-concept studies with limited animal numbers, and thus lack the statistical power for biomarker discovery. Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) is a pioneering multicenter trial investigating preclinical imaging biomarkers of PTE. EpiBios4Rx faced the issue of harmonizing the magnetic resonance imaging (MRI) procedures and imaging data metrics prior to its execution. We present here the harmonization process between three preclinical MRI facilities at the University of Eastern Finland (UEF), the University of Melbourne (Melbourne), and the University of California, Los Angeles (UCLA), and evaluate the uniformity of the obtained MRI data. Adult, male rats underwent a lateral fluid percussion injury (FPI) and were followed by MRI 2 days, 9 days, 1 month, and 5 months post-injury. Ex vivo scans of fixed brains were conducted 7 months post-injury as an end point follow-up. Four MRI modalities were used: T2-weighted imaging, multi-gradient-echo imaging, diffusion-weighted imaging, and magnetization transfer imaging, and acquisition parameters for each modality were tailored to account for the different field strengths (4.7 T and 7 T) and different MR hardwares used at the three participating centers. Pilot data collection resulted in comparable image quality across sites. In interim analysis (of data obtained by April 30, 2018), the within-site variation of the quantified signal properties was low, while some differences between sites remained. In T2-weighted images the signal-to-noise ratios were high at each site, being 35 at UEF, 48 at Melbourne, and 32 at UCLA (p

Published

2019

34. Harmonization of pipeline for preclinical multicenter plasma protein and miRNA biomarker discovery in a rat model of post-traumatic epileptogenesis.

Author

Kamnaksh, Alaa, Puhakka, Noora, Ali, Idrish, Smith, Gregory, Aniceto, Roxanne, McCullough, Jesse, Das Gupta, Shalini, Ndode-Ekane, Xavier Ekolle, Brady, Rhys, Casillas-Espinosa, Pablo, Hudson, Matt, Santana-Gomez, Cesar, Immonen, Riikka, Abreu, Pedro Andrade de, Jones, Nigel, Shultz, Sandy, Staba, Richard J, O'Brien, Terence J, Agoston, Denes, and Pitkänen, Asla

Subjects

Animals, Rats, Rats, Sprague-Dawley, Epilepsy, Post-Traumatic, Disease Models, Animal, Blood Proteins, Hemoglobins, Nerve Tissue Proteins, MicroRNAs, RNA, Messenger, Protein Array Analysis, Statistics, Nonparametric, Proteomics, Computational Biology, Homeostasis, Time Factors, International Cooperation, Biomarkers, Case report form, Common data elements, Post-traumatic epilepsy, Quality control, Standardization, Traumatic brain injury, Epilepsy, Neurosciences, Biotechnology, Physical Injury - Accidents and Adverse Effects, Brain Disorders, Traumatic Head and Spine Injury, Traumatic Brain Injury (TBI), Neurodegenerative, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

The Epilepsy Bioinformatics Study for Antiepileptogenic Therapy (EpiBioS4Rx) is an international, multicenter, multidisciplinary study aimed at preventing epileptogenesis (EpiBioS4Rx: https://epibios.loni.usc.edu/). One of the study's major objectives is the discovery of diagnostic, prognostic, and predictive plasma protein and microRNA (miRNA) biomarkers that are sensitive, specific, and translatable to the human condition. Epilepsy due to structural brain abnormalities, secondary to neurological insults such as traumatic brain injury (TBI), currently represents ∼50% of all epilepsy cases. In the preclinical EpiBioS4Rx study, TBI was induced in adult male Sprague Dawley rats using a standardized protocol for lateral fluid-percussion injury. Whole blood was collected from the tail vein at baseline and 2, 9 and 30 days post-injury and processed for plasma separation. Biomaterial properties, sample preparation and integrity, and choice of analysis platform can significantly impact measured marker levels and, in turn, interpretation with respect to injury and/or other variables. We present here the results of procedural harmonization for the first 320 rats included in the EpiBioS4Rx study study, from three international research centers, and preliminary proteomic and miRNA analyses. We also discuss experimental considerations for establishing rigorous quality controls with the goal of harmonizing operating procedures across study sites, and delivering high-quality specimens for preclinical biomarker discovery in a rat model of post-traumatic epilepsy (PTE).

Published

2019

35. Delta oscillation coupled propagating fast ripples precede epileptiform discharges in patients with focal epilepsy

Author

Weiss, Shennan A., Sheybani, Laurent, Seenarine, Nitish, Fried, Itzhak, Wu, Chengyuan, Sharan, Ashwini, Engel, Jerome, Jr, Sperling, Michael R., Nir, Yuval, and Staba, Richard J.

Published

2022

36. Nonictal EEG biomarkers for diagnosis and treatment.

Author

Engel, Jerome, Bragin, Anatol, and Staba, Richard

Subjects

Biomarkers, Epilepsy, pHFOs, Neurosciences, Clinical Research, Brain Disorders, Neurodegenerative, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Neurological

Abstract

There are no reliable nonictal biomarkers for epilepsy, electroencephalography (EEG) or otherwise, but efforts to identify biomarkers that would predict the development of epilepsy after a potential epileptogenic insult, diagnose the existence of epilepsy, or assess the effects of antiseizure or antiepileptogenic interventions are relying heavily on electrophysiology. The most promising EEG biomarkers to date are pathologic high-frequency oscillations (pHFOs), brief EEG events in the range of 100 to 600 Hz, which are believed to reflect summated action potentials from synchronously bursting neurons. Studies of patients with epilepsy, and experimental animal models, have been based primarily on direct brain recording, which makes pHFOs potentially useful for localizing the epileptogenic zone for surgical resection, but application for other diagnostic and therapeutic purposes is limited. Consequently, recent efforts have involved identification of HFOs recorded with scalp electrodes, and with magnetoencephalography, which may reflect the same pathophysiologic mechanisms as pHFOs recorded directly from the brain. The search is also on for other EEG changes that might serve as epilepsy biomarkers, and candidates include arcuate rhythms, which may reflect repetitive pHFOs, reduction in theta rhythm, which correlates with epileptogenesis in several rodent models of epilepsy, and shortened sleep spindles that correlate with ictogenesis.

Published

2018

37. Low-voltage fast seizures in humans begin with increased interneuron firing.

Author

Elahian, Bahareh, Lado, Nathan E, Mankin, Emily, Vangala, Sitaram, Misra, Amrit, Moxon, Karen, Fried, Itzhak, Sharan, Ashwini, Yeasin, Mohammed, Staba, Richard, Bragin, Anatol, Avoli, Massimo, Sperling, Michael R, Engel, Jerome, and Weiss, Shennan A

Subjects

Gyrus Cinguli, Temporal Lobe, Interneurons, Humans, Seizures, Electroencephalography, Retrospective Studies, Electrodes, Implanted, Action Potentials, Adult, Middle Aged, Female, Male, Young Adult, Neurodegenerative, Neurosciences, Brain Disorders, Epilepsy, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

ObjectiveIntracellular recordings from cells in entorhinal cortex tissue slices show that low-voltage fast (LVF) onset seizures are generated by inhibitory events. Here, we determined whether increased firing of interneurons occurs at the onset of spontaneous mesial-temporal LVF seizures recorded in patients.MethodsThe seizure onset zone (SOZ) was identified using visual inspection of the intracranial electroencephalogram. We used wavelet clustering and temporal autocorrelations to characterize changes in single-unit activity during the onset of LVF seizures recorded from microelectrodes in mesial-temporal structures. Action potentials generated by principal neurons and interneurons (ie, putative excitatory and inhibitory neurons) were distinguished using waveform morphology and K-means clustering.ResultsFrom a total of 200 implanted microelectrodes in 9 patients during 13 seizures, we isolated 202 single units; 140 (69.3%) of these units were located in the SOZ, and 40 (28.57%) of them were classified as inhibitory. The waveforms of both excitatory and inhibitory units remained stable during the LVF epoch (p > > 0.05). In the mesial-temporal SOZ, inhibitory interneurons increased their firing rate during LVF seizure onset (p

Published

2018

38. Getting the best outcomes from epilepsy surgery.

Author

Vakharia, Vejay N, Duncan, John S, Witt, Juri-Alexander, Elger, Christian E, Staba, Richard, and Engel, Jerome

Subjects

Humans, Epilepsy, Treatment Outcome, Neurosurgical Procedures, Clinical Sciences, Neurosciences, Neurology & Neurosurgery

Abstract

Neurosurgery is an underutilized treatment that can potentially cure drug-refractory epilepsy. Careful, multidisciplinary presurgical evaluation is vital for selecting patients and to ensure optimal outcomes. Advances in neuroimaging have improved diagnosis and guided surgical intervention. Invasive electroencephalography allows the evaluation of complex patients who would otherwise not be candidates for neurosurgery. We review the current state of the assessment and selection of patients and consider established and novel surgical procedures and associated outcome data. We aim to dispel myths that may inhibit physicians from referring and patients from considering neurosurgical intervention for drug-refractory focal epilepsies. Ann Neurol 2018;83:676-690.

Published

2018

39. A method for the topographical identification and quantification of high frequency oscillations in intracranial electroencephalography recordings.

Author

Waldman, Zachary J, Shimamoto, Shoichi, Song, Inkyung, Orosz, Iren, Bragin, Anatol, Fried, Itzhak, Engel, Jerome, Staba, Richard, Sperling, Michael R, and Weiss, Shennan A

Subjects

Humans, Sensitivity and Specificity, Software, Adult, Aged, Middle Aged, Female, Male, Gamma Rhythm, Electrocorticography, Filter ringing, High-frequency oscillation, Ripple, Topography, Wavelet, Clinical Research, Clinical Trials and Supportive Activities, Engineering, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo develop a reliable software method using a topographic analysis of time-frequency plots to distinguish ripple (80-200 Hz) oscillations that are often associated with EEG sharp waves or spikes (RonS) from sinusoid-like waveforms that appear as ripples but correspond with digital filtering of sharp transients contained in the wide bandwidth EEG.MethodsA custom algorithm distinguished true from false ripples in one second intracranial EEG (iEEG) recordings using wavelet convolution, identifying contours of isopower, and categorizing these contours into sets of open or closed loop groups. The spectral and temporal features of candidate groups were used to classify the ripple, and determine its duration, frequency, and power. Verification of detector accuracy was performed on the basis of simulations, and visual inspection of the original and band-pass filtered signals.ResultsThe detector could distinguish simulated true from false ripple on spikes (RonS). Among 2934 visually verified trials of iEEG recordings and spectrograms exhibiting RonS the accuracy of the detector was 88.5% with a sensitivity of 81.8% and a specificity of 95.2%. The precision was 94.5% and the negative predictive value was 84.0% (N = 12). Among, 1,370 trials of iEEG recording exhibiting RonS that were reviewed blindly without spectrograms the accuracy of the detector was 68.0%, with kappa equal to 0.01 ± 0.03. The detector successfully distinguished ripple from high spectral frequency 'fast ripple' oscillations (200-600 Hz), and characterize ripple duration and spectral frequency and power. The detector was confounded by brief bursts of gamma (30-80 Hz) activity in 7.31 ± 6.09% of trials, and in 30.2 ± 14.4% of the true RonS detections ripple duration was underestimated.ConclusionsCharacterizing the topographic features of a time-frequency plot generated by wavelet convolution is useful for distinguishing true oscillations from false oscillations generated by filter ringing.SignificanceCategorizing ripple oscillations and characterizing their properties can improve the clinical utility of the biomarker.

Published

2018

40. Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively.

Author

Shimamoto, Shoichi, Waldman, Zachary J, Orosz, Iren, Song, Inkyung, Bragin, Anatol, Fried, Itzhak, Engel, Jerome, Staba, Richard, Sharan, Ashwini, Wu, Chengyuan, Sperling, Michael R, and Weiss, Shennan A

Subjects

Humans, Principal Component Analysis, Adolescent, Adult, Child, Female, Male, Signal-To-Noise Ratio, Intraoperative Neurophysiological Monitoring, Electrocorticography, Detector, High-frequency oscillation, Independent component analysis, Ripple, Brain Disorders, Clinical Research, Neurosciences, Engineering, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo develop and validate a detector that identifies ripple (80-200 Hz) events in intracranial EEG (iEEG) recordings in a referential montage and utilizes independent component analysis (ICA) to eliminate or reduce high-frequency artifact contamination. Also, investigate the correspondence of detected ripples and the seizure onset zone (SOZ).MethodsiEEG recordings from 16 patients were first band-pass filtered (80-600 Hz) and Infomax ICA was next applied to derive the first independent component (IC1). IC1 was subsequently pruned, and an artifact index was derived to reduce the identification of high-frequency events introduced by the reference electrode signal. A Hilbert detector identified ripple events in the processed iEEG recordings using amplitude and duration criteria. The identified ripple events were further classified and characterized as true or false ripple on spikes, or ripples on oscillations by utilizing a topographical analysis to their time-frequency plot, and confirmed by visual inspection.ResultsThe signal to noise ratio was improved by pruning IC1. The precision of the detector for ripple events was 91.27 ± 4.3%, and the sensitivity of the detector was 79.4 ± 3.0% (N = 16 patients, 5842 ripple events). The sensitivity and precision of the detector was equivalent in iEEG recordings obtained during sleep or intra-operatively. Across all the patients, true ripple on spike rates and also the rates of false ripple on spikes, that were generated due to filter ringing, classified the seizure onset zone (SOZ) with an area under the receiver operating curve (AUROC) of >76%. The magnitude and spectral content of true ripple on spikes generated in the SOZ was distinct as compared with the ripples generated in the NSOZ (p

Published

2018

41. Automated preprocessing and phase-amplitude coupling analysis of scalp EEG discriminates infantile spasms from controls during wakefulness

Author

Miyakoshi, Makoto, Nariai, Hiroki, Rajaraman, Rajsekar R., Bernardo, Danilo, Shrey, Daniel W., Lopour, Beth A., Sim, Myung Shin, Staba, Richard J., and Hussain, Shaun A.

Published

2021

42. Bimodal coupling of ripples and slower oscillations during sleep in patients with focal epilepsy.

Author

Song, Inkyung, Orosz, Iren, Chervoneva, Inna, Waldman, Zachary J, Fried, Itzhak, Wu, Chengyuan, Sharan, Ashwini, Salamon, Noriko, Gorniak, Richard, Dewar, Sandra, Bragin, Anatol, Engel, Jerome, Sperling, Michael R, Staba, Richard, and Weiss, Shennan A

Subjects

Brain, Humans, Epilepsies, Partial, Brain Mapping, Sleep, Sleep Stages, Female, Male, Brain Waves, Electrocorticography, Epilepsy, Intracranial electroencephalography, Phase-event amplitude coupling, Ripples, Sleep oscillations, Neurosciences, Neurodegenerative, Sleep Research, Brain Disorders, Clinical Research, Clinical Sciences, Neurology & Neurosurgery

Abstract

OBJECTIVE:Differentiating pathologic and physiologic high-frequency oscillations (HFOs) is challenging. In patients with focal epilepsy, HFOs occur during the transitional periods between the up and down state of slow waves. The preferred phase angles of this form of phase-event amplitude coupling are bimodally distributed, and the ripples (80-150 Hz) that occur during the up-down transition more often occur in the seizure-onset zone (SOZ). We investigated if bimodal ripple coupling was also evident for faster sleep oscillations, and could identify the SOZ. METHODS:Using an automated ripple detector, we identified ripple events in 40-60 min intracranial electroencephalography (iEEG) recordings from 23 patients with medically refractory mesial temporal lobe or neocortical epilepsy. The detector quantified epochs of sleep oscillations and computed instantaneous phase. We utilized a ripple phasor transform, ripple-triggered averaging, and circular statistics to investigate phase event-amplitude coupling. RESULTS:We found that at some individual recording sites, ripple event amplitude was coupled with the sleep oscillatory phase and the preferred phase angles exhibited two distinct clusters (p

Published

2017

43. Update on the mechanisms and roles of high-frequency oscillations in seizures and epileptic disorders.

Author

Jiruska, Premysl, Alvarado-Rojas, Catalina, Schevon, Catherine, Staba, Richard, Stacey, William, Wendling, Fabrice, and Avoli, Massimo

Subjects

Computer models, Epilepsy, Epileptogenesis, Fast ripples, High-frequency oscillations, Ictogenesis, Interneurons, Ripples, Seizures, Animals, Brain, Brain Mapping, Brain Waves, Electroencephalography, Epilepsy, Humans, Seizures, Signal Processing, Computer-Assisted

Abstract

High-frequency oscillations (HFOs) are a type of brain activity that is recorded from brain regions capable of generating seizures. Because of the close association of HFOs with epileptogenic tissue and ictogenesis, understanding their cellular and network mechanisms could provide valuable information about the organization of epileptogenic networks and how seizures emerge from the abnormal activity of these networks. In this review, we summarize the most recent advances in the field of HFOs and provide a critical evaluation of new observations within the context of already established knowledge. Recent improvements in recording technology and the introduction of optogenetics into epilepsy research have intensified experimental work on HFOs. Using advanced computer models, new cellular substrates of epileptic HFOs were identified and the role of specific neuronal subtypes in HFO genesis was determined. Traditionally, the pathogenesis of HFOs was explored mainly in patients with temporal lobe epilepsy and in animal models mimicking this condition. HFOs have also been reported to occur in other epileptic disorders and models such as neocortical epilepsy, genetically determined epilepsies, and infantile spasms, which further support the significance of HFOs in the pathophysiology of epilepsy. It is increasingly recognized that HFOs are generated by multiple mechanisms at both the cellular and network levels. Future studies on HFOs combining novel high-resolution in vivo imaging techniques and precise control of neuronal behavior using optogenetics or chemogenetics will provide evidence about the causal role of HFOs in seizures and epileptogenesis. Detailed understanding of the pathophysiology of HFOs will propel better HFO classification and increase their information yield for clinical and diagnostic purposes.

Published

2017

44. ComBating inter‐site differences in field strength: harmonizing preclinical traumatic brain injury MRI data.

Author

Quach, Mara, Ali, Idrish, Shultz, Sandy R., Casillas‐Espinosa, Pablo M., Hudson, Matthew R., Jones, Nigel C., Silva, Juliana C., Yamakawa, Glenn R., Braine, Emma L., Immonen, Riikka, Staba, Richard J., Tohka, Jussi, Harris, Neil G., Gröhn, Olli, O'Brien, Terence J., and Wright, David K.

Subjects

BRAIN injuries, MAGNETIC resonance imaging, SPRAGUE Dawley rats, DIFFUSION magnetic resonance imaging, DIFFUSION tensor imaging

Abstract

Integrating datasets from multiple sites and scanners can increase statistical power for neuroimaging studies but can also introduce significant inter‐site confounds. We evaluated the effectiveness of ComBat, an empirical Bayes approach, to combine longitudinal preclinical MRI data acquired at 4.7 or 9.4 T at two different sites in Australia. Male Sprague Dawley rats underwent MRI on Days 2, 9, 28, and 150 following moderate/severe traumatic brain injury (TBI) or sham injury as part of Project 1 of the NIH/NINDS‐funded Centre Without Walls EpiBioS4Rx project. Diffusion‐weighted and multiple‐gradient‐echo images were acquired, and outcomes included QSM, FA, and ADC. Acute injury measures including apnea and self‐righting reflex were consistent between sites. Mixed‐effect analysis of ipsilateral and contralateral corpus callosum (CC) summary values revealed a significant effect of site on FA and ADC values, which was removed following ComBat harmonization. Bland–Altman plots for each metric showed reduced variability across sites following ComBat harmonization, including for QSM, despite appearing to be largely unaffected by inter‐site differences and no effect of site observed. Following harmonization, the combined inter‐site data revealed significant differences in the imaging metrics consistent with previously reported outcomes. TBI resulted in significantly reduced FA and increased susceptibility in the ipsilateral CC, and significantly reduced FA in the contralateral CC compared with sham‐injured rats. Additionally, TBI rats also exhibited a reversal in ipsilateral CC ADC values over time with significantly reduced ADC at Day 9, followed by increased ADC 150 days after injury. Our findings demonstrate the need for harmonizing multi‐site preclinical MRI data and show that this can be successfully achieved using ComBat while preserving phenotypical changes due to TBI. [ABSTRACT FROM AUTHOR]

Published

2024

45. Simulated resections and RNS placement can optimize post-operative seizure outcomes when guided by fast ripple networks.

Author

weiss, shennan aibel, primary, Sperling, Michael R, additional, Engel, Jerome, additional, Liu, Anli, additional, Fried, Itzhak, additional, Wu, Chengyuan, additional, Doyle, Werner, additional, Mikell, Charles, additional, Mofakham, Sima, additional, Salamon, Noriko, additional, Sim, Myung Shin, additional, Bragin, Anatol, additional, and Staba, Richard J, additional

Published

2024

46. Patterns of subregional cerebellar atrophy across epilepsy syndromes: An ENIGMA‐Epilepsy study

Author

Kerestes, Rebecca, primary, Perry, Andrew, additional, Vivash, Lucy, additional, O'Brien, Terence J., additional, Alvim, Marina K. M., additional, Arienzo, Donatello, additional, Aventurato, Ítalo K., additional, Ballerini, Alice, additional, Baltazar, Gabriel F., additional, Bargalló, Núria, additional, Bender, Benjamin, additional, Brioschi, Ricardo, additional, Bürkle, Eva, additional, Caligiuri, Maria Eugenia, additional, Cendes, Fernando, additional, de Tisi, Jane, additional, Duncan, John S., additional, Engel, Jerome P., additional, Foley, Sonya, additional, Fortunato, Francesco, additional, Gambardella, Antonio, additional, Giacomini, Thea, additional, Guerrini, Renzo, additional, Hall, Gerard, additional, Hamandi, Khalid, additional, Ives‐Deliperi, Victoria, additional, João, Rafael B., additional, Keller, Simon S., additional, Kleiser, Benedict, additional, Labate, Angelo, additional, Lenge, Matteo, additional, Marotta, Cassandra, additional, Martin, Pascal, additional, Mascalchi, Mario, additional, Meletti, Stefano, additional, Owens‐Walton, Conor, additional, Parodi, Costanza B., additional, Pascual‐Diaz, Saül, additional, Powell, David, additional, Rao, Jun, additional, Rebsamen, Michael, additional, Reiter, Johannes, additional, Riva, Antonella, additional, Rüber, Theodor, additional, Rummel, Christian, additional, Scheffler, Freda, additional, Severino, Mariasavina, additional, Silva, Lucas S., additional, Staba, Richard J., additional, Stein, Dan J., additional, Striano, Pasquale, additional, Taylor, Peter N., additional, Thomopoulos, Sophia I., additional, Thompson, Paul M., additional, Tortora, Domenico, additional, Vaudano, Anna Elisabetta, additional, Weber, Bernd, additional, Wiest, Roland, additional, Winston, Gavin P., additional, Yasuda, Clarissa L., additional, Zheng, Hong, additional, McDonald, Carrie R., additional, Sisodiya, Sanjay M., additional, and Harding, Ian H., additional

Published

2024

47. Ripples on spikes show increased phase-amplitude coupling in mesial temporal lobe epilepsy seizure-onset zones.

Author

Weiss, Shennan A, Orosz, Iren, Salamon, Noriko, Moy, Stephanie, Wei, Linqing, Van't Klooster, Maryse A, Knight, Robert T, Harper, Ronald M, Bragin, Anatol, Fried, Itzhak, Engel, Jerome, and Staba, Richard J

Subjects

Brain, Humans, Epilepsy, Temporal Lobe, Imaging, Three-Dimensional, Magnetic Resonance Imaging, Electroencephalography, Retrospective Studies, Electrodes, Implanted, Tomography Scanners, X-Ray Computed, Adult, Middle Aged, Female, Male, Young Adult, Brain Waves, Epileptiform discharge, High-frequency oscillation, Intracranial EEG, Mesial temporal lobe epilepsy, Ripple, Epilepsy, Temporal Lobe, Imaging, Three-Dimensional, Electrodes, Implanted, Tomography Scanners, X-Ray Computed, Neurodegenerative, Brain Disorders, Clinical Research, Neurosciences, Neurological, Neurology & Neurosurgery, Clinical Sciences

Abstract

ObjectiveRipples (80-150 Hz) recorded from clinical macroelectrodes have been shown to be an accurate biomarker of epileptogenic brain tissue. We investigated coupling between epileptiform spike phase and ripple amplitude to better understand the mechanisms that generate this type of pathologic ripple (pRipple) event.MethodsWe quantified phase amplitude coupling (PAC) between epileptiform electroencephalography (EEG) spike phase and ripple amplitude recorded from intracranial depth macroelectrodes during episodes of sleep in 12 patients with mesial temporal lobe epilepsy. PAC was determined by (1) a phasor transform that corresponds to the strength and rate of ripples coupled with spikes, and a (2) ripple-triggered average to measure the strength, morphology, and spectral frequency of the modulating and modulated signals. Coupling strength was evaluated in relation to recording sites within and outside the seizure-onset zone (SOZ).ResultsBoth the phasor transform and ripple-triggered averaging methods showed that ripple amplitude was often robustly coupled with epileptiform EEG spike phase. Coupling was found more regularly inside than outside the SOZ, and coupling strength correlated with the likelihood a macroelectrode's location was within the SOZ (p < 0.01). The ratio of the rate of ripples coupled with EEG spikes inside the SOZ to rates of coupled ripples in non-SOZ was greater than the ratio of rates of ripples on spikes detected irrespective of coupling (p < 0.05). Coupling strength correlated with an increase in mean normalized ripple amplitude (p < 0.01), and a decrease in mean ripple spectral frequency (p < 0.05).SignificanceGeneration of low-frequency (80-150 Hz) pRipples in the SOZ involves coupling between epileptiform spike phase and ripple amplitude. The changes in excitability reflected as epileptiform spikes may also cause clusters of pathologically interconnected bursting neurons to grow and synchronize into aberrantly large neuronal assemblies.

Published

2016

48. The progression of electrophysiologic abnormalities during epileptogenesis after experimental traumatic brain injury.

Author

Reid, Aylin Y, Bragin, Anatol, Giza, Christopher C, Staba, Richard J, and Engel, Jerome

Subjects

Animals, Rats, Rats, Sprague-Dawley, Epilepsy, Post-Traumatic, Disease Models, Animal, Disease Progression, Electroencephalography, Percussion, Brain Mapping, Electrodes, Implanted, Video Recording, Male, Functional Laterality, Brain Waves, Brain Injuries, Traumatic, Biomarker, Lateral fluid percussion injury, Posttraumatic epilepsy, Seizure, Neurodegenerative, Injury - Traumatic brain injury, Neurosciences, Epilepsy, Brain Disorders, Injury - Trauma - (Head and Spine), Injury (total) Accidents/Adverse Effects, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Aetiology, 2.1 Biological and endogenous factors, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

ObjectivePosttraumatic epilepsy (PTE) accounts for 20% of acquired epilepsies. Experimental models are important for studying epileptogenesis. We previously reported that repetitive high-frequency oscillations with spikes (rHFOSs) occur early after lateral fluid percussion injury (FPI) and may be a biomarker for PTE. The objective of this study was to use multiple electrodes in rat hippocampal and neocortical regions to describe the long-term electroencephalographic and behavioral evolution of rHFOSs and epileptic seizures after traumatic brain injury (TBI).MethodsAdult male rats underwent mild, moderate, or severe FPI or sham injury followed by video-electroencephalography (EEG) recordings with a combination of 16 neocortical and hippocampal electrodes at an early, intermediate, or late time-point after injury, up to 52 weeks. Recordings were analyzed for the presence of rHFOSs and seizures.ResultsAnalysis was done on 28 rats with FPI and 7 shams. Perilesional rHFOSs were recorded in significantly more rats after severe (70.3%) than mild (20%) injury or shams (14.3%). Frequency of occurrence was significantly highest in the early (10.8/h) versus late group (3.2/h). Late focal seizures originating from the same electrodes were recorded in significantly more rats in the late (87.5%) versus early period (22.2%), occurring almost exclusively in injured rats. Seizure duration increased significantly over time, averaging 19 s at the beginning of the early period and 27 s at the end of the late period. Seizure frequency also increased significantly over time, from 4.4 per week in the early group to 26.4 per week in the late group. Rarely, rats displayed early seizures or generalized seizures.SignificanceFPI results in early rHFOSs and later spontaneous focal seizures arising from peri-lesional neocortex, supporting its use as a model for PTE. Epilepsy severity increased over time and was related to injury severity. The association between early rHFOSs and later focal seizures suggests that rHFOSs may be a potential noninvasive biomarker of PTE.

Published

2016

49. Pathologic electrographic changes after experimental traumatic brain injury.

Author

Bragin, Anatol, Li, Lin, Almajano, Joyel, Alvarado-Rojas, Catalina, Reid, Aylin Y, Staba, Richard J, and Engel, Jerome

Subjects

Neocortex, Animals, Rats, Rats, Sprague-Dawley, Epilepsy, Post-Traumatic, Disease Models, Animal, Electroencephalography, Percussion, Analysis of Variance, Electrodes, Implanted, Male, Brain Waves, Brain Injuries, Traumatic, Epileptogenesis, Pathologic high frequency oscillations, Repetitive HFOs and spikes, Seizure, Spindles, Traumatic brain injury, Epilepsy, Injury (total) Accidents/Adverse Effects, Neurosciences, Injury - Trauma - (Head and Spine), Injury - Traumatic brain injury, Brain Disorders, Neurodegenerative, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo investigate possible electroencephalography (EEG) correlates of epileptogenesis after traumatic brain injury (TBI) using the fluid percussion model.MethodsExperiments were conducted on adult 2- to 4-month-old male Sprague-Dawley rats. Two groups of animals were studied: (1) the TBI group with depth and screw electrodes implanted immediately after the fluid percussion injury (FPI) procedure, and (2) a naive age-matched control group with the same electrode implantation montage. Pairs of tungsten microelectrodes (50 μm outer diameter) and screw electrodes were implanted in neocortex inside the TBI core, areas adjacent to TBI, and remote areas. EEG activity, recorded on the day of FPI, and continuously for 2 weeks, was analyzed for possible electrographic biomarkers of epileptogenesis. Video-EEG monitoring was also performed continuously in the TBI group to capture electrographic and behavioral seizures until the caps came off (28-189 days), and for 1 week, at 2, 3, and 6 months of age, in the control group.ResultsPathologic high-frequency oscillations (pHFOs) with a central frequency between 100 and 600 Hz, were recorded from microelectrodes, beginning during the first two post-FPI weeks, in 7 of 12 animals in the TBI group (58%) and never in the controls. pHFOs only occurred in cortical areas within or adjacent to the TBI core. These were associated with synchronous multiunit discharges and popSpikes, duration 15-40 msec. Repetitive pHFOs and EEG spikes (rHFOSs) formed paroxysmal activity, with a unique arcuate pattern, in the frequency band 10-16 Hz in the same areas as isolated pHFOs, and these events were also recorded by screw electrodes. Although loss of caps prevented long-term recordings from all rats, pHFOs and rHFOSs occurred during the first 2 weeks in all four animals that later developed seizures, and none of the rats without these events developed late seizures.SignificancepHFOs, similar to those associated with epileptogenesis in the status rat model of epilepsy, may also reflect epileptogenesis after FPI. rHFOSs could be noninvasive biomarkers of epileptogenesis.

Published

2016

50. Characterization of long-range functional connectivity in epileptic networks by neuronal spike-triggered local field potentials

Author

Lopour, Beth A, Staba, Richard J, Stern, John M, Fried, Itzhak, and Ringach, Dario L

Subjects

Biomedical and Clinical Sciences, Engineering, Neurosciences, Biomedical Engineering, Clinical Research, Brain Disorders, Neurodegenerative, Epilepsy, 2.1 Biological and endogenous factors, Aetiology, Neurological, Action Potentials, Adult, Brain, Brain Mapping, Female, Humans, Male, Microelectrodes, Nerve Net, Neurons, seizure, multi-unit activity, local field potential, temporal lobe, frontal lobe, Clinical Sciences, Biomedical engineering

Abstract

ObjectiveQuantifying the relationship between microelectrode-recorded multi-unit activity (MUA) and local field potentials (LFPs) in distinct brain regions can provide detailed information on the extent of functional connectivity in spatially widespread networks. These methods are common in studies of cognition using non-human animal models, but are rare in humans. Here we applied a neuronal spike-triggered impulse response to electrophysiological recordings from the human epileptic brain for the first time, and we evaluate functional connectivity in relation to brain areas supporting the generation of seizures.ApproachBroadband interictal electrophysiological data were recorded from microwires adapted to clinical depth electrodes that were implanted bilaterally using stereotactic techniques in six presurgical patients with medically refractory epilepsy. MUA and LFPs were isolated in each microwire, and we calculated the impulse response between the MUA on one microwire and the LFPs on a second microwire for all possible MUA/LFP pairs. Results were compared to clinical seizure localization, including sites of seizure onset and interictal epileptiform discharges.Main resultsWe detected significant interictal long-range functional connections in each subject, in some cases across hemispheres. Results were consistent between two independent datasets, and the timing and location of significant impulse responses reflected anatomical connectivity. However, within individual subjects, the spatial distribution of impulse responses was unique. In two subjects with clear seizure localization and successful surgery, the epileptogenic zone was associated with significant impulse responses.SignificanceThe results suggest that the spike-triggered impulse response can provide valuable information about the neuronal networks that contribute to seizures using only interictal data. This technique will enable testing of specific hypotheses regarding functional connectivity in epilepsy and the relationship between functional properties and imaging findings. Beyond epilepsy, we expect that the impulse response could be more broadly applied as a measure of long-range functional connectivity in studies of cognition.

Published

2016