Your search keyword '"Greg Worrell"' showing total 59 results

1. Corrigendum: Proceedings of the Eighth Annual Deep Brain Stimulation Think Tank: Advances in Optogenetics, Ethical Issues Affecting DBS Research, Neuromodulatory Approaches for Depression, Adaptive Neurostimulation, and Emerging DBS Technologies

Author

Vinata Vedam-Mai, Karl Deisseroth, James Giordano, Gabriel Lazaro-Munoz, Winston Chiong, Nanthia Suthana, Jean-Philippe Langevin, Jay Gill, Wayne Goodman, Nicole R. Provenza, Casey H. Halpern, Rajat S. Shivacharan, Tricia N. Cunningham, Sameer A. Sheth, Nader Pouratian, Katherine W. Scangos, Helen S. Mayberg, Andreas Horn, Kara A. Johnson, Christopher R. Butson, Ro'ee Gilron, Coralie de Hemptinne, Robert Wilt, Maria Yaroshinsky, Simon Little, Philip Starr, Greg Worrell, Prasad Shirvalkar, Edward Chang, Jens Volkmann, Muthuraman Muthuraman, Sergiu Groppa, Andrea A. Kühn, Luming Li, Matthew Johnson, Kevin J. Otto, Robert Raike, Steve Goetz, Chengyuan Wu, Peter Silburn, Binith Cheeran, Yagna J. Pathak, Mahsa Malekmohammadi, Aysegul Gunduz, Joshua K. Wong, Stephanie Cernera, Wei Hu, Aparna Wagle Shukla, Adolfo Ramirez-Zamora, Wissam Deeb, Addie Patterson, Kelly D. Foote, and Michael S. Okun

Subjects

DBS (deep brain stimulation), neuroethics, optogenetics, novel hardware, adaptive DBS, neuroimaging, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2021

2. Seizure Diaries and Forecasting With Wearables: Epilepsy Monitoring Outside the Clinic

Author

Benjamin H. Brinkmann, Philippa J. Karoly, Ewan S. Nurse, Sonya B. Dumanis, Mona Nasseri, Pedro F. Viana, Andreas Schulze-Bonhage, Dean R. Freestone, Greg Worrell, Mark P. Richardson, and Mark J. Cook

Subjects

wearable devices, seizure detection, seizure forecasting, multidian cycles, machine learning, epilepsy, Neurology. Diseases of the nervous system, RC346-429

Abstract

It is a major challenge in clinical epilepsy to diagnose and treat a disease characterized by infrequent seizures based on patient or caregiver reports and limited duration clinical testing. The poor reliability of self-reported seizure diaries for many people with epilepsy is well-established, but these records remain necessary in clinical care and therapeutic studies. A number of wearable devices have emerged, which may be capable of detecting seizures, recording seizure data, and alerting caregivers. Developments in non-invasive wearable sensors to measure accelerometry, photoplethysmography (PPG), electrodermal activity (EDA), electromyography (EMG), and other signals outside of the traditional clinical environment may be able to identify seizure-related changes. Non-invasive scalp electroencephalography (EEG) and minimally invasive subscalp EEG may allow direct measurement of seizure activity. However, significant network and computational infrastructure is needed for continuous, secure transmission of data. The large volume of data acquired by these devices necessitates computer-assisted review and detection to reduce the burden on human reviewers. Furthermore, user acceptability of such devices must be a paramount consideration to ensure adherence with long-term device use. Such devices can identify tonic–clonic seizures, but identification of other seizure semiologies with non-EEG wearables is an ongoing challenge. Identification of electrographic seizures with subscalp EEG systems has recently been demonstrated over long (>6 month) durations, and this shows promise for accurate, objective seizure records. While the ability to detect and forecast seizures from ambulatory intracranial EEG is established, invasive devices may not be acceptable for many individuals with epilepsy. Recent studies show promising results for probabilistic forecasts of seizure risk from long-term wearable devices and electronic diaries of self-reported seizures. There may also be predictive value in individuals' symptoms, mood, and cognitive performance. However, seizure forecasting requires perpetual use of a device for monitoring, increasing the importance of the system's acceptability to users. Furthermore, long-term studies with concurrent EEG confirmation are lacking currently. This review describes the current evidence and challenges in the use of minimally and non-invasive devices for long-term epilepsy monitoring, the essential components in remote monitoring systems, and explores the feasibility to detect and forecast impending seizures via long-term use of these systems.

Published

2021

3. Proceedings of the Eighth Annual Deep Brain Stimulation Think Tank: Advances in Optogenetics, Ethical Issues Affecting DBS Research, Neuromodulatory Approaches for Depression, Adaptive Neurostimulation, and Emerging DBS Technologies

Author

Vinata Vedam-Mai, Karl Deisseroth, James Giordano, Gabriel Lazaro-Munoz, Winston Chiong, Nanthia Suthana, Jean-Philippe Langevin, Jay Gill, Wayne Goodman, Nicole R. Provenza, Casey H. Halpern, Rajat S. Shivacharan, Tricia N. Cunningham, Sameer A. Sheth, Nader Pouratian, Katherine W. Scangos, Helen S. Mayberg, Andreas Horn, Kara A. Johnson, Christopher R. Butson, Ro’ee Gilron, Coralie de Hemptinne, Robert Wilt, Maria Yaroshinsky, Simon Little, Philip Starr, Greg Worrell, Prasad Shirvalkar, Edward Chang, Jens Volkmann, Muthuraman Muthuraman, Sergiu Groppa, Andrea A. Kühn, Luming Li, Matthew Johnson, Kevin J. Otto, Robert Raike, Steve Goetz, Chengyuan Wu, Peter Silburn, Binith Cheeran, Yagna J. Pathak, Mahsa Malekmohammadi, Aysegul Gunduz, Joshua K. Wong, Stephanie Cernera, Wei Hu, Aparna Wagle Shukla, Adolfo Ramirez-Zamora, Wissam Deeb, Addie Patterson, Kelly D. Foote, and Michael S. Okun

Subjects

DBS (deep brain stimulation), neuroethics, optogenetics, novel hardware, adaptive DBS, neuroimaging, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

We estimate that 208,000 deep brain stimulation (DBS) devices have been implanted to address neurological and neuropsychiatric disorders worldwide. DBS Think Tank presenters pooled data and determined that DBS expanded in its scope and has been applied to multiple brain disorders in an effort to modulate neural circuitry. The DBS Think Tank was founded in 2012 providing a space where clinicians, engineers, researchers from industry and academia discuss current and emerging DBS technologies and logistical and ethical issues facing the field. The emphasis is on cutting edge research and collaboration aimed to advance the DBS field. The Eighth Annual DBS Think Tank was held virtually on September 1 and 2, 2020 (Zoom Video Communications) due to restrictions related to the COVID-19 pandemic. The meeting focused on advances in: (1) optogenetics as a tool for comprehending neurobiology of diseases and on optogenetically-inspired DBS, (2) cutting edge of emerging DBS technologies, (3) ethical issues affecting DBS research and access to care, (4) neuromodulatory approaches for depression, (5) advancing novel hardware, software and imaging methodologies, (6) use of neurophysiological signals in adaptive neurostimulation, and (7) use of more advanced technologies to improve DBS clinical outcomes. There were 178 attendees who participated in a DBS Think Tank survey, which revealed the expansion of DBS into several indications such as obesity, post-traumatic stress disorder, addiction and Alzheimer’s disease. This proceedings summarizes the advances discussed at the Eighth Annual DBS Think Tank.

Published

2021

4. Physiological and pathological high frequency oscillations in focal epilepsy

Author

Jan Cimbalnik, Benjamin Brinkmann, Vaclav Kremen, Pavel Jurak, Brent Berry, Jamie Van Gompel, Matt Stead, and Greg Worrell

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Objective This study investigates high‐frequency oscillations (HFOs; 65–600 Hz) as a biomarker of epileptogenic brain and explores three barriers to their clinical translation: (1) Distinguishing pathological HFOs (pathHFO) from physiological HFOs (physHFO). (2) Classifying tissue under individual electrodes as epileptogenic (3) Reproducing results across laboratories. Methods We recorded HFOs using intracranial EEG (iEEG) in 90 patients with focal epilepsy and 11 patients without epilepsy. In nine patients with epilepsy putative physHFOs were induced by cognitive or motor tasks. HFOs were identified using validated detectors. A support vector machine (SVM) using HFO features was developed to classify tissue under individual electrodes as normal or epileptogenic. Results There was significant overlap in the amplitude, frequency, and duration distributions for spontaneous physHFO, task induced physHFO, and pathHFO, but the amplitudes of the pathHFO were higher (P

Published

2018

5. 4512 Allopregnanolone Dose Finding for Status Epilepticus Treatment by Pharmacokinetic-Pharmacodynamic Modeling using Quantitative EEG in Dogs

Author

Edward “Ned” Patterson, Irene Vuu, Dorota Zolkowska, Chun-Yi Wu, Ilo Leppik, Greg Worrell, Vaclav Kremen, and James Cloyd

Subjects

Medicine

Abstract

OBJECTIVES/GOALS: Allopregnanolone (ALLO), a modulator of GABAA receptors, may be useful as a treatment for human and canine benzodiazepine-refractory status epilepticus (SE). Our objective was to develop a phamacokinetic-pharmacodynamic (PKPD) model relating ALLO plasma concentrations to electroencephalographic (EEG) effects in dogs. METHODS/STUDY POPULATION: Four healthy dogs and one dog with epilepsy that had implanted intracranial electrodes were utilized. ALLO doses ranging from 1-6 mg/kg were administered IV over 5 min. EEG data were collected during four IM doses (1-2 mg/kg). Blood samples were collected up to 6 hr following dosing. ALLO concentrations were measured using HPLC-MS/MS. Power density was determined in EEG bands using a custom algorithm. A two-compartment link PKPD model was developed to describe the relation between ALLO plasma concentration and change in EEG power in the alpha, beta, delta and theta bands. RESULTS/ANTICIPATED RESULTS: ALLO caused a rapid increase in absolute power density in all EEG bands measured (1-4, >4 – 8, >8 – 12, >12 – 25, and >25 – 100 Hz). The onset of effect was rapid (1-3 min) and demonstrated by frequency band and dose analysis. Concentration-EEG data were best fit by a two-compartment PK model and sigmoidal Emax PD indirect link model. The beta frequency band was most sensitive, showing increases in power at the lowest ALLO concentrations. The EC50 concentration for the beta frequency was ~270 ng/mL. The EC50 values for effects on the other frequency bands were ~500-700 ng /mL. In conclusion, IV ALLO causes a rapid effect on EEG that can be used to determine minimal plasma concentrations associated with target engagement. DISCUSSION/SIGNIFICANCE OF IMPACT: Dose selection for future clinical trials will use the effective concentrations determined here in conjunction with studies in animal status epilepticus models. Studies are planned in client owned dogs with epilepsy to evaluate clinical efficacy in dogs and as nonclinical proof-of-concept evidence supporting translational studies in people. CONFLICT OF INTEREST DESCRIPTION: Michael Rogawski and Dorota Zolkowska are named as inventors on patent applications claiming use of neuroactive steroids including allopregnanolone and ganaxolone in the treatment of status epilepticus.

Published

2020

6. Evolving Applications, Technological Challenges and Future Opportunities in Neuromodulation: Proceedings of the Fifth Annual Deep Brain Stimulation Think Tank

Author

Adolfo Ramirez-Zamora, James J. Giordano, Aysegul Gunduz, Peter Brown, Justin C. Sanchez, Kelly D. Foote, Leonardo Almeida, Philip A. Starr, Helen M. Bronte-Stewart, Wei Hu, Cameron McIntyre, Wayne Goodman, Doe Kumsa, Warren M. Grill, Harrison C. Walker, Matthew D. Johnson, Jerrold L. Vitek, David Greene, Daniel S. Rizzuto, Dong Song, Theodore W. Berger, Robert E. Hampson, Sam A. Deadwyler, Leigh R. Hochberg, Nicholas D. Schiff, Paul Stypulkowski, Greg Worrell, Vineet Tiruvadi, Helen S. Mayberg, Joohi Jimenez-Shahed, Pranav Nanda, Sameer A. Sheth, Robert E. Gross, Scott F. Lempka, Luming Li, Wissam Deeb, and Michael S. Okun

Subjects

deep brain stimulation, neuromodulation, epilepsy, Parkinson's disease, tremor, obsessive compulsive disorder, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The annual Deep Brain Stimulation (DBS) Think Tank provides a focal opportunity for a multidisciplinary ensemble of experts in the field of neuromodulation to discuss advancements and forthcoming opportunities and challenges in the field. The proceedings of the fifth Think Tank summarize progress in neuromodulation neurotechnology and techniques for the treatment of a range of neuropsychiatric conditions including Parkinson's disease, dystonia, essential tremor, Tourette syndrome, obsessive compulsive disorder, epilepsy and cognitive, and motor disorders. Each section of this overview of the meeting provides insight to the critical elements of discussion, current challenges, and identified future directions of scientific and technological development and application. The report addresses key issues in developing, and emphasizes major innovations that have occurred during the past year. Specifically, this year's meeting focused on technical developments in DBS, design considerations for DBS electrodes, improved sensors, neuronal signal processing, advancements in development and uses of responsive DBS (closed-loop systems), updates on National Institutes of Health and DARPA DBS programs of the BRAIN initiative, and neuroethical and policy issues arising in and from DBS research and applications in practice.

Published

2018

7. Relative entropy is an easy‐to‐use invasive electroencephalographic biomarker of the epileptogenic zone

Author

Vojtech Travnicek, Petr Klimes, Jan Cimbalnik, Josef Halamek, Pavel Jurak, Benjamin Brinkmann, Irena Balzekas, Chifaou Abdallah, François Dubeau, Birgit Frauscher, Greg Worrell, and Milan Brazdil

Subjects

Neurology, Neurology (clinical)

Published

2023

8. Distinct signatures of loss of consciousness in focal impaired awareness versus tonic-clonic seizures

Author

Elsa Juan, Urszula Górska, Csaba Kozma, Cynthia Papantonatos, Tom Bugnon, Colin Denis, Vaclav Kremen, Greg Worrell, Aaron F Struck, Lisa M Bateman, Edward M Merricks, Hal Blumenfeld, Giulio Tononi, Catherine Schevon, and Melanie Boly

Subjects

Neurology (clinical)

Abstract

Loss of consciousness is a hallmark of many epileptic seizures and carries risks of serious injury and sudden death. While cortical sleep-like activities accompany loss of consciousness during focal impaired awareness seizures, the mechanisms of loss of consciousness during focal to bilateral tonic-clonic seizures remain unclear. Quantifying differences in markers of cortical activation and ictal recruitment between focal impaired awareness and focal to bilateral tonic-clonic seizures may also help us to understand their different consequences for clinical outcomes and to optimize neuromodulation therapies. We quantified clinical signs of loss of consciousness and intracranial EEG activity during 129 focal impaired awareness and 50 focal to bilateral tonic-clonic from 41 patients. We characterized intracranial EEG changes both in the seizure onset zone and in areas remote from the seizure onset zone with a total of 3386 electrodes distributed across brain areas. First, we compared the dynamics of intracranial EEG sleep-like activities: slow-wave activity (1–4 Hz) and beta/delta ratio (a validated marker of cortical activation) during focal impaired awareness versus focal to bilateral tonic-clonic. Second, we quantified differences between focal to bilateral tonic-clonic and focal impaired awareness for a marker validated to detect ictal cross-frequency coupling: phase-locked high gamma (high-gamma phased-locked to low frequencies) and a marker of ictal recruitment: the epileptogenicity index. Third, we assessed changes in intracranial EEG activity preceding and accompanying behavioural generalization onset and their correlation with electromyogram channels. In addition, we analysed human cortical multi-unit activity recorded with Utah arrays during three focal to bilateral tonic-clonic seizures. Compared to focal impaired awareness, focal to bilateral tonic-clonic seizures were characterized by deeper loss of consciousness, even before generalization occurred. Unlike during focal impaired awareness, early loss of consciousness before generalization was accompanied by paradoxical decreases in slow-wave activity and by increases in high-gamma activity in parieto-occipital and temporal cortex. After generalization, when all patients displayed loss of consciousness, stronger increases in slow-wave activity were observed in parieto-occipital cortex, while more widespread increases in cortical activation (beta/delta ratio), ictal cross-frequency coupling (phase-locked high gamma) and ictal recruitment (epileptogenicity index). Behavioural generalization coincided with a whole-brain increase in high-gamma activity, which was especially synchronous in deep sources and could not be explained by EMG. Similarly, multi-unit activity analysis of focal to bilateral tonic-clonic revealed sustained increases in cortical firing rates during and after generalization onset in areas remote from the seizure onset zone. Overall, these results indicate that unlike during focal impaired awareness, the neural signatures of loss of consciousness during focal to bilateral tonic-clonic consist of paradoxical increases in cortical activation and neuronal firing found most consistently in posterior brain regions. These findings suggest differences in the mechanisms of ictal loss of consciousness between focal impaired awareness and focal to bilateral tonic-clonic and may account for the more negative prognostic consequences of focal to bilateral tonic-clonic.

Published

2022

9. Stimulation to probe, excite, and inhibit the epileptic brain

Author

Birgit Frauscher, Fabrice Bartolomei, Maxime O. Baud, Rachel J. Smith, Greg Worrell, and Brian N. Lundstrom

Subjects

Neurology, Neurology (clinical), 610 Medicine & health

Abstract

Direct cortical stimulation has been applied in epilepsy for nearly one century and has experienced a renaissance given unprecedented opportunities to probe, excite and inhibit the human brain. Evidence suggests stimulation can increase diagnostic and therapeutic utility in patients with drug-resistant epilepsies. However, choosing appropriate stimulation parameters is not a trivial issue, which is further complicated by the fact that epilepsy is characterized by complex brain state dynamics. In this article derived from discussions at the ICTALS 2022 conference, we succinctly review the literature on cortical stimulation applied acutely and chronically to the epileptic brain for localization, monitoring, and therapeutic purposes. In particular, we discuss how stimulation is used to probe brain excitability, discuss evidence on usefulness of stimulation to trigger and stop seizures, review therapeutic applications of stimulation, and finally discuss how stimulation parameters are impacted by brain dynamics. Although research has advanced considerably over the past decade, there are still significant hurdles to optimize use of this technique. For example, it remains unclear to what extent short timescale diagnostic biomarkers can predict long-term outcomes and to what extent these biomarkers add information to already existing biomarkers from passive EEG recordings. Further questions include the extent to which closed loop stimulation offers advantages over open loop stimulation, what the optimal closed loop timescales may be, and whether biomarker-informed stimulation can lead to seizure freedom. The ultimate goal of bioelectronic medicine remains not just to stop seizures but rather to cure epilepsy and its comorbidities.

Published

2023

10. Responsive neurostimulation with low-frequency stimulation

Author

Juan Luis Alcala‐Zermeno, Keith Starnes, Nicholas M. Gregg, Greg Worrell, and Brian N. Lundstrom

Subjects

Neurology, Neurology (clinical), Article

Abstract

Deep brain stimulation and responsive neurostimulation (RNS) use high-frequency stimulation (HFS) per the pivotal trials and manufacturer-recommended therapy protocols. However, not all patients respond to HFS. In this retrospective case series, 10 patients implanted with the RNS System were programmed with low-frequency stimulation (LFS) to treat their seizures; nine of these patients were previously treated with HFS (100 Hz or greater). LFS was defined as frequency 10 Hz. Burst duration was increased to at least 1000 ms. With HFS, patients had a median seizure reduction (MSR) of 13% (interquartile range [IQR] = -67 to 54) after a median of 19 months (IQR = 8-49). In contrast, LFS was associated with a 67% MSR (IQR = 13-95) when compared to HFS and 76% MSR (IQR = 43-91) when compared to baseline prior to implantation. Charge delivered per hour and pulses per day were not significantly different between HFS and LFS, although time stimulated per day was longer for LFS (228 min) than for HFS (7 min). There were no LFS-specific adverse effects reported by any of the patients. LFS could represent an alternative, effective method for delivering stimulation in focal drug-resistant epilepsy patients treated with the RNS System.

Published

2022

11. Forecasting cycles of seizure likelihood

Author

Benjamin H. Brinkmann, Sonya B. Dumanis, Levin Kuhlmann, Andreas Schulze-Bonhage, Matias I. Maturana, Greg Worrell, Philippa J. Karoly, David B. Grayden, Ewan S. Nurse, Mark P. Richardson, Daniel E. Payne, Dean R. Freestone, and Mark J. Cook

Subjects

0301 basic medicine, medicine.medical_specialty, Activities of daily living, Audiology, Electroencephalography, Medical Records, 03 medical and health sciences, Seizure onset, Epilepsy, 0302 clinical medicine, Seizure diary, Seizures, Humans, Medicine, Likelihood Functions, medicine.diagnostic_test, business.industry, Mobile apps, medicine.disease, Mobile Applications, Clinical neurology, 030104 developmental biology, Neurology, Cohort, Self Report, Neurology (clinical), business, Algorithms, 030217 neurology & neurosurgery, Forecasting

Abstract

Objective Seizure unpredictability is rated as one of the most challenging aspects of living with epilepsy. Seizure likelihood can be influenced by a range of environmental and physiological factors that are difficult to measure and quantify. However, some generalizable patterns have been demonstrated in seizure onset. A majority of people with epilepsy exhibit circadian rhythms in their seizure times, and many also show slower, multiday patterns. Seizure cycles can be measured using a range of recording modalities, including self-reported electronic seizure diaries. This study aimed to develop personalized forecasts from a mobile seizure diary app. Methods Forecasts based on circadian and multiday seizure cycles were tested pseudoprospectively using data from 50 app users (mean of 109 seizures per subject). Individuals' strongest cycles were estimated from their reported seizure times and used to derive the likelihood of future seizures. The forecasting approach was validated using self-reported events and electrographic seizures from the Neurovista dataset, an existing database of long-term electroencephalography that has been widely used to develop forecasting algorithms. Results The validation dataset showed that forecasts of seizure likelihood based on self-reported cycles were predictive of electrographic seizures for approximately half the cohort. Forecasts using only mobile app diaries allowed users to spend an average of 67.1% of their time in a low-risk state, with 14.8% of their time in a high-risk warning state. On average, 69.1% of seizures occurred during high-risk states and 10.5% of seizures occurred in low-risk states. Significance Seizure diary apps can provide personalized forecasts of seizure likelihood that are accurate and clinically relevant for electrographic seizures. These results have immediate potential for translation to a prospective seizure forecasting trial using a mobile diary app. It is our hope that seizure forecasting apps will one day give people with epilepsy greater confidence in managing their daily activities.

Published

2020

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

Author

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

Subjects

fast ripple, high-frequency oscillation, Epilepsy, brain network, epilepsy surgery, Neurosciences, General Engineering, Neurodegenerative, Brain Disorders

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

13. Invasive neuromodulation for epilepsy: Comparison of multiple approaches from a single center

Author

Juan Luis, Alcala-Zermeno, Nicholas M, Gregg, Keith, Starnes, Jayawant N, Mandrekar, Jamie J, Van Gompel, Kai, Miller, Greg, Worrell, and Brian N, Lundstrom

Subjects

Adult, Drug Resistant Epilepsy, Behavioral Neuroscience, Epilepsy, Treatment Outcome, Anterior Thalamic Nuclei, Neurology, Seizures, Deep Brain Stimulation, Humans, Neurology (clinical), Child, Article

Abstract

BACKGROUND: Drug resistant epilepsy (DRE) patients not amenable to epilepsy surgery can benefit from neurostimulation. Few data compare different neuromodulation strategies. OBJECTIVE: Compare five invasive neuromodulation strategies for treatment of DRE: anterior thalamic nuclei deep brain stimulation (ANT-DBS), centromedian thalamic nuclei DBS (CM-DBS), responsive neurostimulation (RNS), chronic subthreshold stimulation (CSS), and vagus nerve stimulation (VNS). METHODS: Single center retrospective review and phone survey for patients implanted with invasive neuromodulation for 2004–2021. RESULTS: N=159 (ANT-DBS=38, CM-DBS=19, RNS=30, CSS=32, VNS=40). Total median seizure reduction (MSR) was 61% for the entire cohort (IQR 5–90) and in descending order: CSS (85%), CM-DBS (63%), ANT-DBS (52%), RNS (50%), and VNS (50%); p=0.07. Responder rate was 60% after median follow-up time of 26 months. Seizure severity, life satisfaction and quality of sleep were improved. Cortical stimulation (RNS and CSS) was associated with improved seizure reduction compared to subcortical stimulation (ANT-DBS, CM-DBS, and VNS) (67% vs. 52%). Effectiveness was similar for focal epilepsy vs generalized epilepsy, closed loop vs open loop stimulation, pediatric vs. adult cases, and high frequency (>100 Hz) vs low frequency (

Published

2022

14. Distinct signatures of loss of consciousness during Focal Impaired Awareness versus Focal to Bilateral Tonic Clonic seizures

Author

Catherine A. Schevon, Lisa M. Bateman, Cynthia Papantonatos, Mélanie Boly, Colin Denis, Greg Worrell, Vaclav Kremen, Elsa Juan, Aaron F. Struck, Csaba Kozma, Hal Blumenfeld, Edward M. Merricks, Tom Bugnon, Urszula Górska, and Giulio Tononi

Subjects

medicine.anatomical_structure, business.industry, Neuronal firing, Neuromodulation, Medicine, Tonic (music), Ictal, Seizure onset zone, business, Neuroscience, Intracranial eeg, Sudden death, Cortex (botany)

Abstract

Loss of consciousness (LOC) is a hallmark of many epileptic seizures and carries risks of serious injury and sudden death. While cortical sleep-like activities accompany LOC during focal impaired awareness (FIA) seizures, the mechanisms of LOC during focal to bilateral tonic-clonic (FBTC) seizures remain unclear. Quantifying differences in markers of cortical activation and ictal recruitment between FIA and FBTC seizures may also help to understand their different consequences for clinical outcomes and to optimize neuromodulation therapies.We quantified clinical signs of LOC and intracranial EEG (iEEG) activity during 129 FIA and 50 FBTC from 41 patients. We characterized iEEG changes both in the seizure onset zone (SOZ) and in areas remote from SOZ with a total of 3386 electrodes distributed across brain areas. First, we compared the dynamics of iEEG sleep-like activities: slow-wave activity (SWA; 1-4 Hz) and beta/delta ratio (B/D; a validated marker of cortical activation) during FIA vs. FBTC. Second, we quantified differences between FBTC and FIA for a marker validated to detect ictal cross-frequency coupling: phase-locked high-gamma (PLHG; high gamma phased locked to low frequencies) and a marker of ictal recruitment: the epileptogenicity index (i.e. the number of channels crossing an energy ratio threshold for high vs. low frequency power). Third, we assessed changes in iEEG activity preceding and accompanying behavioral generalization onset and their correlation with electromyogram (EMG) channels. In addition, we analyzed human cortical multi-unit activity recorded with Utah arrays during three FBTC.Compared to FIA, FBTC seizures were characterized by deeper LOC and by stronger increases in SWA in parieto-occipital cortex. FBTC also displayed more widespread increases in cortical activation (B/D), ictal cross-frequency coupling (PLHG) and ictal recruitment (epileptogenicity index). Even before generalization, FBTC displayed deeper LOC; this early LOC was accompanied by a paradoxical increase in B/D in fronto-parietal cortex. Behavioral generalization coincided with complete loss of responsiveness and a subsequent increase in high-gamma in the whole brain, which was especially synchronous in deep sources and could not be explained by EMG. Similarly, multi-unit activity analysis of FBTC revealed sustained increases in cortical firing rates during and after generalization onset in areas remote from the SOZ.Unlike during FIA, LOC during FBTC is characterized by a paradoxical increase in cortical activation and neuronal firing. These findings suggest differences in the mechanisms of ictal LOC between FIA and FBTC and may account for the more negative prognostic consequences of FBTC.

Published

2021

15. Low frequency interictal EEG biomarker for localizing seizures

Author

Ben Brinkmann, Greg Worrell, and Brian Nils Lundstrom

Subjects

medicine.medical_specialty, business.industry, Seizure onset zone, Predictive value, Seizure onset, Eeg activity, Internal medicine, Interictal eeg, Cardiology, medicine, Biomarker (medicine), Ictal, Subdural electrodes, business

Abstract

ObjectiveWe want to identify seizure onset zone (SOZ) from interictal EEG biomarkers. We hypothesize that a combination of interictal EEG biomarkers, including a novel low frequency marker, can predict mesial temporal involvement and can assist in prognosis related to surgical resections.MethodsInterictal direct current wide bandwidth invasive EEG recordings from 83 patients implanted with 5,111 electrodes were retrospectively studied. Logistic regression was used to classify electrodes and patient outcomes. A feed-forward neural network was implemented to understand putative mechanisms.ResultsInterictal infraslow frequency EEG activity was decreased for SOZ electrodes while faster frequencies such as delta (2-4 Hz) and beta-gamma (20-50 Hz) activity were increased. These spectral changes comprised a novel interictal EEG biomarker that was significantly increased for mesial temporal SOZ electrodes compared to non-SOZ electrodes. Interictal EEG biomarkers correctly classified mesial temporal SOZ electrodes with a specificity of 87% and positive predictive value of 80%. These interictal EEG biomarkers also correctly classified patient outcomes after surgical resection with a specificity of 91% and positive predictive value of 87%.InterpretationInterictal infraslow EEG activity is decreased near the SOZ while higher frequency power is increased, suggesting distinct underlying physiologic mechanisms. Decreased interictal infraslow activity may reflect the loss of neural inhibition. Narrowband interictal EEG power bands provide information about the SOZ and can help predict mesial temporal involvement in seizure onset. Together with interictal epileptiform discharges and high frequency oscillations, these interictal biomarkers may provide prognostic information prior to surgical resection.

Published

2021

16. Independent dynamics of slow, intermediate, and fast intracranial EEG spectral activities during human memory formation

Author

Petr Nejedly, Michal T. Kucewicz, Greg Worrell, Victoria S. Marks, Krishnakant Saboo, Çağdaş Topçu, Kremen, and Thayib Tp

Subjects

Text mining, business.industry, Computer science, Dynamics (music), Human memory, business, Intracranial eeg, Neuroscience

Abstract

A wide spectrum of brain rhythms are engaged throughout the human cortex in cognitive functions. How the rhythms of various low and high frequencies are spatiotemporally coordinated across the human brain during memory processing is inconclusive. They can either be coordinated together across a wide range of the frequency spectrum or induced in specific bands. We used a large dataset of human intracranial electroencephalography (iEEG) to parse the spatiotemporal dynamics of spectral activities induced during formation of verbal memories. Encoding of words for subsequent free recall activated slow theta, intermediate alpha and beta, and fast gamma frequency power in discrete cortical sites. A majority of the electrode sites recorded activity in only one of these frequencies, except for the visual cortex where spectral power was induced across multiple bands. Each frequency band showed characteristic dynamics of the induced power specific to cortical area and hemisphere. The power of the low, intermediate, and fast activities propagated in distinct spatiotemporal patterns across the visual, temporal and prefrontal cortical areas as the words were presented for encoding. Our results suggest anatomically and temporally distributed spectral activities in the formation of human memory.

Published

2021

17. Seizure likelihood varies with day-to-day variations in sleep duration in patients with refractory focal epilepsy: A longitudinal EEG investigation

Author

Mark J. Cook, Petr Nejedly, Kremen, Raymond C. Boston, Gerla, Katrina L. Dell, Anthony N. Burkitt, Daniel E. Payne, Wendyl D'Souza, Matias I. Maturana, Greg Worrell, Levin Kuhlmann, Filip Mivalt, David B. Grayden, Ben Brinkmann, Dean R. Freestone, and Lenka L

Subjects

medicine.medical_specialty, medicine.diagnostic_test, business.industry, Rapid eye movement sleep, Eye movement, Electroencephalography, Audiology, Logistic regression, medicine.disease, Sleep in non-human animals, Epilepsy, Refractory, medicine, business, Sleep duration

Abstract

BackgroundWhile the effects of prolonged sleep deprivation (≥24 hours) on seizure occurrence has been thoroughly explored, little is known about the effects of day-to-day variations in the duration and quality of sleep on seizure probability. A better understanding of the interaction between sleep and seizures may help to improve seizure management.MethodsTo explore how sleep and epileptic seizures are associated, we analysed continuous intracranial EEG recordings collected from 10 patients with refractory focal epilepsy undergoing ordinary life activities. A total of 4340 days of sleep-wake data were analysed (average 434 days per patient). EEG data were sleep scored using a semi-automated machine learning approach into wake, stages one, two, and three non-rapid eye movement sleep, and rapid eye movement sleep categories.FindingsSeizure probability changes with day-to-day variations in sleep duration. Logistic regression models revealed that an increase in sleep duration, by 1·66 ± 0·52 hours, lowered the odds of seizure by 27% in the following 48 hours. Following a seizure, patients slept for longer durations and if a seizure occurred during sleep, then sleep quality was also reduced with increased time spent aroused from sleep and reduced REM sleep.InterpretationOur results demonstrate that day-to-day deviations from regular sleep duration correlates with changes in seizure probability. Sleeping longer, by 1·66 ± 0·52 hours, may offer protective effects for patients with refractory focal epilepsy, reducing seizure risk. Furthermore, the occurrence of a seizure may disrupt sleep patterns by elongating sleep and, if the seizure occurs during sleep, reducing its quality.FundingAustralian National Health and Medical Research Council, US National Institutes of Health and Czech Technical University in Prague and Epilepsy Foundation of America Innovation Institute

Published

2021

18. Typical somatomotor physiology of the hand is preserved in a patient with an amputated arm: An ECoG case study

Author

Nicholas M. Gregg, Kai J. Miller, Gabriela Ojeda Valencia, Dora Hermes, Greg Worrell, Thomas J. Richner, Nick F. Ramsey, Kendall H. Lee, and Max van den Boom

Subjects

Physiology, Movement, Cognitive Neuroscience, Computer applications to medicine. Medical informatics, R858-859.7, Thumb, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Motor system, Paralysis, medicine, Humans, 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, BCI, RC346-429, Stroke, Brain–computer interface, business.industry, 05 social sciences, Regular Article, Electroencephalography, Hand, medicine.disease, ECoG, Electrophysiology, medicine.anatomical_structure, Neurology, Upper arm amputation, Arm, Motor cortex, Electrocorticography, Neurology (clinical), Brainstem, Neurology. Diseases of the nervous system, medicine.symptom, business, 030217 neurology & neurosurgery, Limb loss

Abstract

Highlights • Electrophysiology of amputated hand preserved in contralateral sensorimotor cortex. • Typical focal increase of HFB power and distributed decrease in LFB. • Finger representations are intact and decodable at high (>90%) accuracy. • Optimal decoding 1–3 s after onset, with at least 13–13 mm cortical coverage. • Electrophysiology remain intact after long term amputation and can be used for BCIs., Electrophysiological signals in the human motor system may change in different ways after deafferentation, with some studies emphasizing reorganization while others propose retained physiology. Understanding whether motor electrophysiology is retained over longer periods of time can be invaluable for patients with paralysis (e.g. ALS or brainstem stroke) when signals from sensorimotor areas may be used for communication or control over neural prosthetic devices. In addition, a maintained electrophysiology can potentially benefit the treatment of phantom limb pains through prolonged use of these signals in a brain-machine interface (BCI). Here, we were presented with the unique opportunity to investigate the physiology of the sensorimotor cortex in a patient with an amputated arm using electrocorticographic (ECoG) measurements. While implanted with an ECoG grid for clinical evaluation of electrical stimulation for phantom limb pain, the patient performed attempted finger movements with the contralateral (lost) hand and executed finger movements with the ipsilateral (healthy) hand. The electrophysiology of the sensorimotor cortex contralateral to the amputated hand remained very similar to that of hand movement in healthy people, with a spatially focused increase of high-frequency band (65–175 Hz; HFB) power over the hand region and a distributed decrease in low-frequency band (15–28 Hz; LFB) power. The representation of the three different fingers (thumb, index and little) remained intact and HFB patterns could be decoded using support vector learning at single-trial classification accuracies of >90%, based on the first 1–3 s of the HFB response. These results indicate that hand representations are largely retained in the motor cortex. The intact physiological response of the amputated hand, the high distinguishability of the fingers and fast temporal peak are encouraging for neural prosthetic devices that target the sensorimotor cortex.

Published

2021

19. Variability in the location of high frequency oscillations during prolonged intracranial EEG recordings

Author

Hugh J. L. Garton, Oren Sagher, William C. Stacey, Cynthia A. Chestek, Stephen V. Gliske, Greg Worrell, Benjamin H. Brinkmann, Garnett Hegeman, and Zachary T. Irwin

Subjects

Adult, Male, 0301 basic medicine, medicine.medical_specialty, Adolescent, Science, General Physics and Astronomy, Context (language use), Electroencephalography, Blind signal separation, Article, General Biochemistry, Genetics and Molecular Biology, Young Adult, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Text mining, Seizures, Internal medicine, medicine, Humans, Ictal, Child, lcsh:Science, Aged, Multidisciplinary, medicine.diagnostic_test, business.industry, Brain, Infant, General Chemistry, Middle Aged, medicine.disease, Control subjects, Intracranial eeg, 030104 developmental biology, Child, Preschool, Cardiology, Female, lcsh:Q, Electrocorticography, Sleep, business, 030217 neurology & neurosurgery

Abstract

The rate of interictal high frequency oscillations (HFOs) is a promising biomarker of the seizure onset zone, though little is known about its consistency over hours to days. Here we test whether the highest HFO-rate channels are consistent across different 10-min segments of EEG during sleep. An automated HFO detector and blind source separation are applied to nearly 3000 total hours of data from 121 subjects, including 12 control subjects without epilepsy. Although interictal HFOs are significantly correlated with the seizure onset zone, the precise localization is consistent in only 22% of patients. The remaining patients either have one intermittent source (16%), different sources varying over time (45%), or insufficient HFOs (17%). Multiple HFO networks are found in patients with both one and multiple seizure foci. These results indicate that robust HFO interpretation requires prolonged analysis in context with other clinical data, rather than isolated review of short data segments., High frequency oscillations (HFO) are a promising biomarker for identifying epileptogenic zones without the need to monitor spontaneous seizure episodes. Here the authors report that there is much variability in the location of HFOs offering a note of caution toward using HFO locations from short recordings as a guide for surgery.

Published

2018

20. Comparing spiking and slow wave activity from invasive electroencephalography in patients with and without seizures

Author

Jamie J. Van Gompel, Christian Meisel, Matt Stead, Greg Worrell, and Brian Nils Lundstrom

Subjects

Male, 0301 basic medicine, Drug Resistant Epilepsy, medicine.medical_specialty, Stimulation, Seizure onset zone, Electroencephalography, Article, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Seizures, Physiology (medical), Internal medicine, medicine, Humans, In patient, medicine.diagnostic_test, business.industry, Brain, Motor cortex stimulation, medicine.disease, Brain Waves, Sensory Systems, Electrodes, Implanted, 030104 developmental biology, Neurology, Cardiology, Female, Electrocorticography, Epilepsies, Partial, Neurology (clinical), Subdural electrodes, business, 030217 neurology & neurosurgery, Atypical facial pain

Abstract

Objectives To develop quantitative measures for estimating seizure probability, we examine intracranial EEG data from patient groups with three qualitative seizure probabilities: patients with drug resistant focal epilepsy (high), these patients during cortical stimulation (intermediate), and patients who have no history of seizures (low). Methods Patients with focal epilepsy were implanted with subdural electrodes during presurgical evaluation. Patients without seizures were implanted during treatment with motor cortex stimulation for atypical facial pain. Results The rate and amplitude of spikes correlate with qualitative seizure probability across patient groups and with proximity to the seizure onset zone in focal epilepsy patients. Spikes occur earlier during the negative oscillation of underlying slow activity (0.5–2 Hz) when seizure probability is increased. Similarly, coupling between slow and fast activity is increased. Conclusions There is likely a continuum of sharply contoured activity between non-epileptiform and epileptiform. Characteristics of spiking and how spikes relate to slow activity can be combined to predict seizure onset zones. Significance Intracranial EEG data from patients without seizures represent a unique comparison group and highlight changes seen in spiking and slow wave activity with increased seizure probability. Slow wave activity and related physiology are an important potential biomarker for estimating seizure probability.

Published

2018

21. Forecasting Cycles of Seizure Likelihood

Author

Mark J. Cook, Benjamin H. Brinkmann, Levin Kuhlmann, Andreas Schulze-Bonhage, Ewan S. Nurse, Matias I. Maturana, David B. Grayden, Philippa J. Karoly, Greg Worrell, Sonya B. Dumanis, Dean R. Freestone, Mark P. Richardson, and Daniel E. Payne

Subjects

0303 health sciences, medicine.medical_specialty, Activities of daily living, medicine.diagnostic_test, business.industry, Mobile apps, Audiology, Electroencephalography, medicine.disease, 03 medical and health sciences, Epilepsy, Seizure onset, 0302 clinical medicine, Seizure diary, Medicine, business, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SUMMARYObjectiveSeizure unpredictability is rated as one of the most challenging aspects of living with epilepsy. Seizure likelihood can be influenced by a range of environmental and physiological factors that are difficult to measure and quantify. However, some generalizable patterns have been demonstrated in seizure onset. A majority of people with epilepsy exhibit circadian rhythms in their seizure times and many also show slower, multiday patterns. Seizure cycles can be measured using a range of recording modalities, including self-reported electronic seizure diaries. This study aimed to develop personalized forecasts from a mobile seizure diary app.MethodsForecasts based on circadian and multiday seizure cycles were tested pseudo-prospectively using data from 33 app users (mean of 103 seizures per subject). Individual’s strongest cycles were estimated from their reported seizure times and used to derive the likelihood of future seizures. The forecasting approach was validated using self-reported events and electrographic seizures from the Neurovista dataset, an existing database of long-term electroencephalography that has been widely used to develop forecasting algorithms.ResultsThe validation dataset showed that forecasts of seizure likelihood based on self-reported cycles were predictive of electrographic seizures. Forecasts using only mobile app diaries allowed users to spend an average of 62.8% of their time in a low-risk state, with 16.6% of their time in a high-risk warning state. On average, 64.5% of seizures occurred during high-risk states and less than 10% of seizures occurred in low-risk states.SignificanceSeizure diary apps can provide personalized forecasts of seizure likelihood that are accurate and clinically relevant for electrographic seizures. These results have immediate potential for translation to a prospective seizure forecasting trial using a mobile diary app. It is our hope that seizure forecasting apps will one day give people with epilepsy greater confidence in managing their daily activities.

Published

2019

22. Big data in epilepsy: Clinical and research considerations. Report from the Epilepsy Big Data Task Force of the International League Against Epilepsy

Author

Philippe Ryvlin, Samuel Wiebe, Greg Worrell, Colin B. Josephson, Samden D. Lhatoo, Jeffrey Buchhalter, Andreas Schulze-Bonhage, Aristea S. Galanopoulou, Daniel H. Lowenstein, Spiros Denaxas, Kees P.J. Braun, Guo-Qiang Zhang, David J. Thurman, Ingmar Blümcke, Satya S. Sahoo, Katja Kobow, Neda Bernasconi, and Maria Thom

Subjects

0301 basic medicine, Big Data, Biomedical Research, Big data, Advisory Committees, Neuroimaging, 03 medical and health sciences, Epilepsy, Wearable Electronic Devices, 0302 clinical medicine, Deep Learning, Stakeholder Participation, Research Support as Topic, medicine, Electronic Health Records, Humans, Epilepsy surgery, Computer Security, Societies, Medical, Common Data Elements, Task force, business.industry, Information Dissemination, Stakeholder, Petabyte, Brain, Genomics, medicine.disease, Data science, Telemedicine, Clinical trial, 030104 developmental biology, Neurology, Biological Ontologies, Neurology (clinical), Electrocorticography, Smartphone, business, Psychology, International league against epilepsy, 030217 neurology & neurosurgery, Confidentiality

Abstract

Epilepsy is a heterogeneous condition with disparate etiologies and phenotypic and genotypic characteristics. Clinical and research aspects are accordingly varied, ranging from epidemiological to molecular, spanning clinical trials and outcomes, gene and drug discovery, imaging, electroencephalography, pathology, epilepsy surgery, digital technologies, and numerous others. Epilepsy data are collected in the terabytes and petabytes, pushing the limits of current capabilities. Modern computing firepower and advances in machine and deep learning, pioneered in other diseases, open up exciting possibilities for epilepsy too. However, without carefully designed approaches to acquiring, standardizing, curating, and making available such data, there is a risk of failure. Thus, careful construction of relevant ontologies, with intimate stakeholder inputs, provides the requisite scaffolding for more ambitious big data undertakings, such as an epilepsy data commons. In this review, we assess the clinical and research epilepsy landscapes in the big data arena, current challenges, and future directions, and make the case for a systematic approach to epilepsy big data.

Published

2019

23. Chronic subthreshold cortical stimulation and stimulation-related EEG biomarkers for focal epilepsy

Author

Matt Stead, Jamie J. Van Gompel, Brian Nils Lundstrom, Fatemeh Khadjevand, and Greg Worrell

Subjects

0301 basic medicine, focal epilepsy, trial stimulation, medicine.medical_specialty, Alpha (ethology), brain stimulation, Stimulation, Electroencephalography, EEG biomarkers, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Internal medicine, chronic subthreshold cortical stimulation, medicine, Ictal, medicine.diagnostic_test, business.industry, General Engineering, Neurophysiology, medicine.disease, 3. Good health, 030104 developmental biology, Brain stimulation, Cardiology, Biomarker (medicine), Original Article, business, 030217 neurology & neurosurgery

Abstract

Brain stimulation offers an alternative to focal resection for the treatment of focal drug-resistant epilepsy. Chronic subthreshold cortical stimulation is an individualized biomarker-informed open-loop continuous electrical stimulation approach targeting the seizure onset zone and surrounding areas. Before permanent implantation, trial stimulation is performed during invasive monitoring to assess stimulation efficacy as well as to optimize stimulation location and parameters by modifying interictal EEG biomarkers. We present clinical and neurophysiological results from a retrospective analysis of 21 patients, showing a median percent reduction in seizure frequency of 100% and responder rate of 89% with a median follow-up of 27 months. About 40% of patients were free of disabling seizures for a 12-month period or longer. We find that stimulation-induced decreases in delta (1–4 Hz) power and increases in alpha and beta (8–20 Hz) power during trial stimulation correlate with improved long-term clinical outcomes. These results suggest chronic subthreshold cortical stimulation may be an effective alternative approach to treating focal drug-resistant epilepsy and that short-term stimulation-related changes in spectral power may be a useful interictal biomarker and relate to long-term clinical outcome., Focal drug-resistant epilepsy remains challenging to treat. Chronic subthreshold cortical stimulation (CSCS) offers a novel individualized treatment approach that targets the seizure onset zone with continuous electrical stimulation. Stimulation-related changes in EEG biomarkers during trial stimulation may help guide implantation of permanent electrodes., Graphical Abstract Graphical Abstract

Published

2019

24. Multi-feature localization of epileptic foci from interictal, intracranial EEG

Author

Pavel Daniel, Martin Pail, Robert Roman, Vladimir Sladky, Hari Guragain, Milan Brázdil, Petr Nejedly, Benjamin H. Brinkmann, Pavel Jurák, Jan Cimbalnik, Greg Worrell, and Petr Klimes

Subjects

Adult, Male, Computer science, 050105 experimental psychology, Article, Resection, 03 medical and health sciences, Epilepsy, Young Adult, 0302 clinical medicine, Multi feature, Physiology (medical), medicine, Humans, 0501 psychology and cognitive sciences, Ictal, Aged, Retrospective Studies, business.industry, 05 social sciences, Pattern recognition, Electroencephalography, Middle Aged, Drug Resistant Epilepsy, medicine.disease, Intracranial eeg, Sensory Systems, Electrodes, Implanted, Support vector machine, Neurology, Female, Neurology (clinical), Artificial intelligence, Epilepsies, Partial, business, Epileptic foci, 030217 neurology & neurosurgery

Abstract

Objective When considering all patients with focal drug-resistant epilepsy, as high as 40–50% of patients suffer seizure recurrence after surgery. To achieve seizure freedom without side effects, accurate localization of the epileptogenic tissue is crucial before its resection. We investigate an automated, fast, objective mapping process that uses only interictal data. Methods We propose a novel approach based on multiple iEEG features, which are used to train a support vector machine (SVM) model for classification of iEEG electrodes as normal or pathologic using 30 min of inter-ictal recording. Results The tissue under the iEEG electrodes, classified as epileptogenic, was removed in 17/18 excellent outcome patients and was not entirely resected in 8/10 poor outcome patients. The overall best result was achieved in a subset of 9 excellent outcome patients with the area under the receiver operating curve = 0.95. Conclusion SVM models combining multiple iEEG features show better performance than algorithms using a single iEEG marker. Multiple iEEG and connectivity features in presurgical evaluation could improve epileptogenic tissue localization, which may improve surgical outcome and minimize risk of side effects. Significance In this study, promising results were achieved in localization of epileptogenic regions by SVM models that combine multiple features from 30 min of inter-ictal iEEG recordings.

Published

2019

25. Abstract #117: Changes in high frequency activity depend on frequency of electrical stimulation in the human cortex

Author

Joel M. Stein, Bradley C. Lega, Michael R. Sperling, Kathryn A. Davis, Sameer A. Sheth, Robert E. Gross, Ashwini Sharan, Brent M. Berry, Uma R. Mohan, Greg Worrell, Barbara C. Jobst, and Sandhitsu R. Das

Subjects

medicine.anatomical_structure, Chemistry, General Neuroscience, Cortex (anatomy), Biophysics, medicine, Stimulation, Neurology (clinical), Neuroscience, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, lcsh:RC321-571

Published

2019

26. Trial stimulation and chronic subthreshold cortical stimulation to treat focal epilepsy

Author

Matt Stead, J. Van Gompel, Greg Worrell, Brian Nils Lundstrom, and Fatemeh Khadjevand

Subjects

Epilepsy, Subthreshold conduction, business.industry, General Neuroscience, Biophysics, medicine, Stimulation, Neurology (clinical), medicine.disease, business, Neuroscience, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, lcsh:RC321-571

Published

2019

27. MTL functional connectivity predicts stimulation-induced theta power

Author

Kareem A. Zaghloul, James E. Kragel, Sameer A. Sheth, Joel M. Stein, Richard Gorniak, Greg Worrell, Michael R. Sperling, Barbara C. Jobst, Michael J. Kahana, Daniel S. Rizzuto, Ethan A. Solomon, Bradley C. Lega, S. Das, Sarah Seger, Robert E. Gross, and Cory S. Inman

Subjects

Physics, 0303 health sciences, Functional connectivity, Stimulation, Complex network, Theta power, Temporal lobe, White matter, 03 medical and health sciences, Neural activity, 0302 clinical medicine, medicine.anatomical_structure, medicine, Neuroscience, 030217 neurology & neurosurgery, Electrical brain stimulation, 030304 developmental biology

Abstract

/SummaryFocal electrical stimulation of the brain incites a cascade of neural activity that propagates from the stimulated region to both nearby and remote areas, offering the potential to control the activity of brain networks. Understanding how exogenous electrical signals perturb such networks in humans is key to its clinical translation. To investigate this, we applied electrical stimulation to subregions of the medial temporal lobe in 26 neurosurgical patients fitted with indwelling electrodes. Networks of low-frequency (5-13 Hz) spectral coherence predicted stimulation-evoked changes in theta (5-8 Hz) power, but only when stimulation was applied in or adjacent to white matter. Furthermore, these power changes aligned with control-theoretic predictions of how exogenous stimulation flows through complex networks, such as a dispersal of induced activity when functional hubs are targeted. Our results demonstrate that functional connectivity is predictive of causal changes in the brain, but that access to structural connections is necessary to observe such effects.

Published

2018

28. Functional wiring of the human medial temporal lobe

Author

Barbara C. Jobst, Bradley C. Lega, Daniel S. Rizzuto, Cory S. Inman, Ethan A. Solomon, Michael J. Kahana, Greg Worrell, Michael R. Sperling, S. Das, Joel M. Stein, and Richard Gorniak

Subjects

0303 health sciences, Functional connectivity, Theta activity, Dentate gyrus, Subiculum, Hippocampus, Human brain, Biology, Entorhinal cortex, Memory processing, Temporal lobe, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, nervous system, Left entorhinal cortex, Perirhinal cortex, medicine, Verbal memory, Psychology, Neuroscience, Episodic memory, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The medial temporal lobe (MTL) is a locus of episodic memory in the human brain. It is comprised of cytologically distinct subregions that, in concert, give rise to successful encoding and retrieval of context-dependent memories. However, the functional connections between these subregions are poorly understood. To determine functional connectivity among MTL subregions, we had 126 subjects fitted with indwelling electrodes perform a verbal memory task, and asked how encoding or retrieval correlated with interregional synchronization. Using phase-based measures of connectivity, we found that synchronous theta (4-8 Hz) activity underlies successful episodic memory, whereas high-frequencies exhibit desynchronization. Moreover, theta functional connectivity during encoding aligned with key anatomic connections, including critical links between the entorhinal cortex, dentate gyrus, and CA1 of the hippocampus. Retrieval-associated networks demonstrated enhanced involvement of the subiculum, reflecting a substantial reorganization of the encoding-associated network. We posit that coherent theta activity within the MTL marks periods of successful memory, but distinct patterns of connectivity dissociate key stages of memory processing.Significance StatementThe brain functions through the interaction of its distinct parts, but little is known about how such connectivity dynamics relate to learning and memory. We used a large dataset of 126 human subjects with intracranial electrodes to assess patterns of electrical connectivity within the medial temporal lobe – a key region for memory processing – as they performed a memory task. We discovered that unique networks of time-varying, low-frequency interactions correlate with memory encoding and retrieval, specifically in the theta band. Simultaneously, we observed elevated spectral power at high frequencies in these same regions. The result is a complete map of physiological dynamics within the MTL, highlighting how a reorganization of theta networks support distinct memory operations.

Published

2018

29. Widespread theta synchrony and high-frequency desynchronization underlies enhanced cognition

Author

Kareem A. Zaghloul, James E. Kragel, Bradley C. Lega, Joel M. Stein, Michael J. Kahana, Daniel S. Rizzuto, Greg Worrell, Michael R. Sperling, Sameer A. Sheth, Kathryn A. Davis, Ashwini Sharan, Barbara C. Jobst, Ethan A. Solomon, Michal T. Kucewicz, and Cory S. Inman

Subjects

0301 basic medicine, Nervous system, Computer science, Science, Electroencephalography Phase Synchronization, General Physics and Astronomy, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Cognition, Memory, Encoding (memory), Gamma Rhythm, medicine, Connectome, Animals, Humans, Theta Rhythm, lcsh:Science, Multidisciplinary, Gamma power, Brain, General Chemistry, 030104 developmental biology, medicine.anatomical_structure, Asynchronous communication, Mental Recall, lcsh:Q, Neuroscience, 030217 neurology & neurosurgery

Abstract

The idea that synchronous neural activity underlies cognition has driven an extensive body of research in human and animal neuroscience. Yet, insufficient data on intracranial electrical connectivity has precluded a direct test of this hypothesis in a whole-brain setting. Through the lens of memory encoding and retrieval processes, we construct whole-brain connectivity maps of fast gamma (30–100 Hz) and slow theta (3–8 Hz) spectral neural activity, based on data from 294 neurosurgical patients fitted with indwelling electrodes. Here we report that gamma networks desynchronize and theta networks synchronize during encoding and retrieval. Furthermore, for nearly all brain regions we studied, gamma power rises as that region desynchronizes with gamma activity elsewhere in the brain, establishing gamma as a largely asynchronous phenomenon. The abundant phenomenon of theta synchrony is positively correlated with a brain region’s gamma power, suggesting a predominant low-frequency mechanism for inter-regional communication., Synchronous neural activity is related with memory encoding and retrieval, but it is not clear whether this happens across the whole brain. Here, authors use intracranial recordings to show that gamma networks are largely asynchronous, desynchronizing while theta synchronizes during memory encoding and retrieval.

Published

2017

30. Long-Term Measurement of Impedance in Chronically Implanted Depth and Subdural Electrodes During Responsive Neurostimulation in Humans

Author

Kathy Cicora, Martha J. Morrell, Jerry J. Shih, Justin C. Williams, Greg Worrell, Joseph F. Drazkowski, Paul Rutecki, Karl A. Sillay, Brett Wingeier, and Ashwini Sharan

Subjects

Biophysics, Electric Stimulation Therapy, lcsh:RC321-571, Double-Blind Method, Electric Impedance, Humans, Current-controlled stimulation, Medicine, Responsive neurostimulation, Lead (electronics), Electrodes, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Electrical impedance, Epilepsy, business.industry, General Neuroscience, Brain, Impedance, Implantable Neurostimulators, Neuromodulation (medicine), Brain implant, Electrode–tissue interface, Anesthesia, Brain stimulation, Neurology (clinical), business, Subdural electrodes, Biomedical engineering

Abstract

Long-term stability of the electrode-tissue interface may be required to maintain optimal neural recording with subdural and deep brain implants and to permit appropriate delivery of neuromodulation therapy. Although short-term changes in impedance at the electrode-tissue interface are known to occur, long-term changes in impedance have not previously been examined in detail in humans. To provide further information about short- and long-term impedance changes in chronically implanted electrodes, a dataset from 191 persons with medically intractable epilepsy participating in a trial of an investigational responsive neurostimulation device (the RNS(®) System, NeuroPace, Inc.) was reviewed. Monopolar impedance measurements were available for 391 depth and subdural leads containing a total of 1564 electrodes; measurements were available for median 802 days post-implant (range 28-1634). Although there were statistically significant short-term impedance changes, long-term impedance was stable after one year. Impedances for depth electrodes transiently increased during the third week after lead implantation and impedances for subdural electrodes increased over 12 weeks post-implant, then were stable over the subsequent long-term follow-up. Both depth and subdural electrode impedances demonstrated long-term stability, suggesting that the quality of long-term electrographic recordings (the data used to control responsive brain stimulation) can be maintained over time.

Published

2013

31. 2014 Epilepsy Benchmarks Area III: Improve Treatment Options for Controlling Seizures and Epilepsy-Related Conditions Without Side Effects

Author

Dennis, Dlugos, Greg, Worrell, Kathryn, Davis, William, Stacey, Jerzy, Szaflarski, Andres, Kanner, Sridhar, Sunderam, Mike, Rogawski, Patrice, Jackson-Ayotunde, Tobias, Loddenkemper, Beate, Diehl, Brandy, Fureman, and Ray, Dingledine

Subjects

0301 basic medicine, High rate, medicine.medical_specialty, Conceptualization, business.industry, Multiple forms, Intractable epilepsy, Treatment options, Single gene, medicine.disease, 03 medical and health sciences, Epilepsy, 030104 developmental biology, 0302 clinical medicine, Quality of life (healthcare), medicine, Epilepsy Benchmarks, Neurology (clinical), Psychiatry, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

The goals of Epilepsy Benchmark Area III involve identifying areas that are ripe for progress in terms of controlling seizures and patient symptoms in light of the most recent advances in both basic and clinical research. These goals were developed with an emphasis on potential new therapeutic strategies that will reduce seizure burden and improve quality of life for patients with epilepsy. In particular, we continue to support the proposition that a better understanding of how seizures are initiated, propagated, and terminated in different forms of epilepsy is central to enabling new approaches to treatment, including pharmacological as well as surgical and device-oriented approaches. The stubbornly high rate of treatment-resistant epilepsy-one-third of patients-emphasizes the urgent need for new therapeutic strategies, including pharmacological, procedural, device linked, and genetic. The development of new approaches can be advanced by better animal models of seizure initiation that represent salient features of human epilepsy, as well as humanized models such as induced pluripotent stem cells and organoids. The rapid advances in genetic understanding of a subset of epilepsies provide a path to new and direct patient-relevant cellular and animal models, which could catalyze conceptualization of new treatments that may be broadly applicable across multiple forms of epilepsies beyond those arising from variation in a single gene. Remarkable advances in machine learning algorithms and miniaturization of devices and increases in computational power together provide an enhanced opportunity to detect and mitigate seizures in real time via devices that interrupt electrical activity directly or administer effective pharmaceuticals. Each of these potential areas for advance will be discussed in turn.

Published

2016

32. Microseizures and the spatiotemporal scales of human partial epilepsy

Author

Kendall H. Lee, Brian Litt, Benjamin H. Brinkmann, W. Richard Marsh, Matt Stead, Jamie J. Van Gompel, Mark R. Bower, Fredric B. Meyer, and Greg Worrell

Subjects

medicine.diagnostic_test, Neurological disorder, Electroencephalography, medicine.disease, Brain mapping, Epileptogenesis, Stereoelectroencephalography, Epilepsy, Electrophysiology, Convulsion, medicine, Neurology (clinical), medicine.symptom, Psychology, Neuroscience

Abstract

Focal seizures appear to start abruptly and unpredictably when recorded from volumes of brain probed by clinical intracranial electroencephalograms. To investigate the spatiotemporal scale of focal epilepsy, wide-bandwidth electrophysiological recordings were obtained using clinical macro- and research microelectrodes in patients with epilepsy and control subjects with intractable facial pain. Seizure-like events not detectable on clinical macroelectrodes were observed on isolated microelectrodes. These ‘microseizures’ were sparsely distributed, more frequent in brain regions that generated seizures, and sporadically evolved into large-scale clinical seizures. Rare microseizures observed in control patients suggest that this phenomenon is ubiquitous, but their density distinguishes normal from epileptic brain. Epileptogenesis may involve the creation of these topographically fractured microdomains and ictogenesis (seizure generation), the dynamics of their interaction and spread.

Published

2010

33. Ictal SPECT statistical parametric mapping in temporal lobe epilepsy surgery

Author

Terence J. O'Brien, Noojan Kazemi, Benjamin H. Brinkmann, Elson L. So, S. M. Stead, Brian P. Mullan, and Greg Worrell

Subjects

Adult, Male, Time Factors, Adolescent, Electroencephalography, computer.software_genre, Statistical parametric mapping, behavioral disciplines and activities, Ictal-Interictal SPECT Analysis by SPM, Functional Laterality, Temporal lobe, Young Adult, Epilepsy, Voxel, medicine, Humans, Epilepsy surgery, Cysteine, Tomography, Emission-Computed, Single-Photon, Brain Mapping, medicine.diagnostic_test, business.industry, Subtraction, Brain, Articles, Organotechnetium Compounds, Middle Aged, medicine.disease, Magnetic Resonance Imaging, nervous system diseases, Treatment Outcome, Epilepsy, Temporal Lobe, nervous system, Subtraction Technique, Female, Neurology (clinical), Radiopharmaceuticals, Nuclear medicine, business, Psychology, computer

Abstract

Although subtraction ictal SPECT coregistered to MRI (SISCOM) is clinically useful in epilepsy surgery evaluation, it does not determine whether the ictal-interictal subtraction difference is statistically different from the expected random variation between 2 SPECT studies. We developed a statistical parametric mapping and MRI voxel-based method of analyzing ictal-interictal SPECT difference data (statistical ictal SPECT coregistered to MRI [STATISCOM]) and compared it with SISCOM.Two serial SPECT studies were performed in 11 healthy volunteers without epilepsy (control subjects) to measure random variation between serial studies from individuals. STATISCOM and SISCOM images from 87 consecutive patients who had ictal SPECT studies and subsequent temporal lobectomy were assessed by reviewers blinded to clinical data and outcome.Interobserver agreement between blinded reviewers was higher for STATISCOM images than for SISCOM images (kappa = 0.81 vs kappa = 0.36). STATISCOM identified a hyperperfusion focus in 84% of patients, SISCOM in 66% (p0.05). STATISCOM correctly localized the temporal lobe epilepsy (TLE) subtypes (mesial vs lateral neocortical) in 68% of patients compared with 24% by SISCOM (p = 0.02); subgroup analysis of patients without lesions (as determined by MRI) showed superiority of STATISCOM (80% vs 47%; p = 0.04). Moreover, the probability of seizure-free outcome was higher when STATISCOM correctly localized the TLE subtype than when it was indeterminate (81% vs 53%; p = 0.03).Statistical ictal SPECT coregistered to MRI (STATISCOM) was superior to subtraction ictal SPECT coregistered to MRI for seizure localization before temporal lobe epilepsy (TLE) surgery. STATISCOM localization to the correct TLE subtype was prognostically important for postsurgical seizure freedom.

Published

2009

34. High-frequency oscillations in human temporal lobe: simultaneous microwire and clinical macroelectrode recordings

Author

Richard W. Marsh, Fredric B. Meyer, Greg Worrell, Sanqing Hu, Steve Goerss, Gregory J. Cascino, S. Matt Stead, Andrew B. Gardner, and Brian Litt

Subjects

Brain Mapping, Materials science, medicine.diagnostic_test, Oscillation, Ripple, Electroencephalography, Signal Processing, Computer-Assisted, Magnetic Resonance Imaging, Brain mapping, EPILEPSY TEMPORAL LOBE, Intracranial eeg, Article, Temporal Lobe, Stereoelectroencephalography, Electrodes, Implanted, Temporal lobe, Epilepsy, Temporal Lobe, Biological Clocks, medicine, Humans, Neurology (clinical), Neuroscience, Biomedical engineering

Abstract

Neuronal oscillations span a wide range of spatial and temporal scales that extend beyond traditional clinical EEG. Recent research suggests that high-frequency oscillations (HFO), in the ripple (80-250 Hz) and fast ripple (250-1000 Hz) frequency range, may be signatures of epileptogenic brain and involved in the generation of seizures. However, most research investigating HFO in humans comes from microwire recordings, whose relationship to standard clinical intracranial EEG (iEEG) has not been explored. In this study iEEG recordings (DC - 9000 Hz) were obtained from human medial temporal lobe using custom depth electrodes containing both microwires and clinical macroelectrodes. Ripple and fast-ripple HFO recorded from both microwires and clinical macroelectrodes were increased in seizure generating brain regions compared to control regions. The distribution of HFO frequencies recorded from the macroelectrodes was concentrated in the ripple frequency range, compared to a broad distribution of HFO frequencies recorded from microwires. The average frequency of ripple HFO recorded from macroelectrodes was lower than that recorded from microwires (143.3 +/- 49.3 Hz versus 116.3 +/- 38.4, Wilcoxon rank sum P

Published

2008

35. A multi-feature and multi-channel univariate selection process for seizure prediction

Author

Landi M. Parish, Rosana Esteller, George Vachtsevanos, Stephen D. Cranstoun, Greg Worrell, Javier Echauz, Brian Litt, and M. D'Alessandro

Subjects

Time Factors, Feature extraction, Electroencephalography, Sensitivity and Specificity, Probabilistic neural network, Predictive Value of Tests, Seizures, Physiology (medical), False positive paradox, medicine, Humans, False Positive Reactions, Ictal, Prospective Studies, Selection, Genetic, Artificial neural network, medicine.diagnostic_test, business.industry, Seizure types, Reproducibility of Results, Signal Processing, Computer-Assisted, Pattern recognition, Sensory Systems, Electrodes, Implanted, Neurology, Evaluation Studies as Topic, Neurology (clinical), Artificial intelligence, Epileptic seizure, medicine.symptom, Psychology, business, Neuroscience, Algorithms

Abstract

Objective To develop a prospective method for optimizing seizure prediction, given an array of implanted electrodes and a set of candidate quantitative features computed at each contact location. Methods The method employs a genetic-based selection process, and then tunes a probabilistic neural network classifier to predict seizures within a 10 min prediction horizon. Initial seizure and interictal data were used for training, and the remaining IEEG data were used for testing. The method continues to train and learn over time. Results Validation of these results over two workshop patients demonstrated a sensitivity of 100%, and 1.1 false positives per hour for Patient E, using a 2.4 s block predictor, and a failure of the method on Patient B. Conclusions This study demonstrates a prospective, exploratory implementation of a seizure prediction method designed to adapt to individual patients with a wide variety of pre-ictal patterns, implanted electrodes and seizure types. Its current performance is limited likely by the small number of input channels and quantitative features employed in this study, and segmentation of the data set into training and testing sets rather than using all continuous data available. Significance This technique theoretically has the potential to address the challenge presented by the heterogeneity of EEG patterns seen in medication-resistant epilepsy. A more comprehensive implementation utilizing all electrode sites, a broader feature library, and automated multi-feature fusion will be required to fully judge the method's potential for predicting seizures.

Published

2005

36. High-frequency oscillations and seizure generation in neocortical epilepsy

Author

Stephen D. Cranstoun, Gordon H. Baltuch, Rachel Jonas, Brian Litt, Landi M. Parish, and Greg Worrell

Subjects

Analysis of Variance, medicine.diagnostic_test, Thalamus, Central nervous system, Video Recording, Brain, Electroencephalography, medicine.disease, Electrodes, Implanted, Central nervous system disease, Electrophysiology, Epilepsy, medicine.anatomical_structure, medicine, Humans, Epilepsy surgery, Epilepsies, Partial, Neurology (clinical), Sleep, Psychology, Neuroscience, Slow-wave sleep

Abstract

Neocortical seizures are often poorly localized, explosive and widespread at onset, making them poorly amenable to epilepsy surgery in the absence of associated focal brain lesions. We describe, for the first time in an unselected group of patients with neocortical epilepsy, the finding that high-frequency (60-100 Hz) epileptiform oscillations are highly localized in the seizure onset zone, both before and temporally removed from seizure onset. These findings were observed in all six patients with neocortical epilepsy out of 23 consecutive patients implanted with intracranial electrodes for pre-surgical evaluation during the study period. The majority of seizures (62%) in these patients were anticipated by an increase in high-frequency activity in the 20 min prior to neocortical seizure onset. Contrary to observations in normal brain, high-frequency activity was strongly modulated by behavioural state, and was maximal during slow-wave sleep, which may explain the propensity for neocortical onset seizures to begin during sleep. These findings point to an important role for neuromodulatory circuits, probably involving the thalamus, in mechanisms underlying seizure generation in neocortical epilepsy. These findings demonstrate that high-frequency epileptiform oscillations may prove clinically useful in localizing the seizure onset zone in neocortical epilepsy, for identifying periods of increased probability of seizure onset, and in elucidating mechanisms underlying neocortical ictogenesis. Confirmation that prolonged bursts of high-frequency activity may predict focal onset neocortical seizures will require prospective validation on continuous, prolonged recordings in a larger number of patients. Importantly, the results show that the dynamic range utilized in current clinical practice for localization of epileptogenic brain largely ignores fundamental oscillations that are signatures of an epileptogenic brain. It may prove that many currently available clinical EEG systems and EEG analysis methods utilize a dynamic range that discards clinically important information.

Published

2004

37. Long-range temporal correlations in epileptogenic and non-epileptogenic human hippocampus

Author

L.M. Parish, S.M. Stead, Greg Worrell, Stephen D. Cranstoun, Brian Litt, and Page B. Pennell

Subjects

Epilepsy, Quantitative Biology::Neurons and Cognition, medicine.diagnostic_test, Quantitative Biology::Tissues and Organs, General Neuroscience, Hippocampus, Electroencephalography, medicine.disease, Electrophysiology, nervous system, Detrended fluctuation analysis, medicine, Biological neural network, Humans, Psychology, Neuroscience, Mesial temporal lobe epilepsy

Abstract

Epileptogenic human hippocampus generates spontaneous energy fluctuations with a wide range of amplitude and temporal variation, which are often assumed to be entirely random. However, the temporal dynamics of these fluctuations are poorly understood, and the question of whether they exhibit persistent long-range temporal correlations (LRTC) remains unanswered. In this paper we use detrended fluctuation analysis (DFA) to show that the energy fluctuations in human hippocampus show LRTC with power-law scaling, and that these correlations differ between epileptogenic and non-epileptogenic hippocampus. The analysis shows that the energy fluctuations exhibit slower decay of the correlations in the epileptogenic hippocampus compared with the non-epileptogenic hippocampus. The DFA-derived scaling exponents demonstrate that there are LRTC of energy fluctuations in human hippocampus, and that the temporal persistence of energy fluctuations is characterized by a bias for large (small) energy fluctuations to be followed by large (small) energy fluctuations. Furthermore, we find that in the period of time leading up to seizures there is no change in the scaling exponents that characterize the LRTC of energy fluctuations. The fact that the LRTC of energy fluctuations do not change as seizures approach provides evidence that the local neuronal network dynamics do not change in the period before seizures, and that seizures in mesial temporal lobe epilepsy may be triggered by an influence that is external to the hippocampus. The presence of LRTC with power-law scaling does not imply a specific mechanism, but the finding that temporal correlations decay more slowly in epileptogenic hippocampus provides electrophysiologic evidence that the underlying neuronal dynamics are different within the epileptogenic hippocampus compared with contralateral hippocampus. We briefly discuss possible neurobiological mechanisms for LRTC of the energy fluctuations in hippocampus.

Published

2004

38. Plenary speakers: Reliable interfaces with the peripheral nervous system

Author

Timothy J. Denison, Grace C. Y. Peng, Warren M. Grill, Nigel H. Lovell, Dominique Durand, Yuan Liu, Xiaoping Hu, Theodore W. Berger, Dario Farina, Jerrold L. Vitek, Silvestro Micera, Greg Worrell, David Guiraud, Lee E. Miller, P. Hunter Peckham, Todd A. Kuiken, Grégoire Courtine, Lei Ding, Bruce C. Wheeler, Jose C. Principe, Bin He, Metin Akay, Brian Litt, Mark S. Humayun, Gert Cauwenberghs, Terrence J. Sejnowski, Kaiming Ye, V. Reggie Edgerton, Nitish V. Thakor, Steven J. Schiff, Shangkai Gao, Justin C. Sanchez, John A. White, and Paul Sajda

Subjects

Neuromorphic engineering, Computer science, Neural Prosthesis, Motor control, Neural engineering, Neuroscience, Neuromodulation (medicine), Neural decoding, Rehabilitation engineering, Brain–computer interface

Abstract

The following topics are discussed: Neural Robotics and Rehabilitation; Suspicious Coincidences in the Brain; Deep Brain Stimulation - Challenges and Opportunities; Translational Neuroengineering; Engineering Memories: A Cognitive Neural Prosthesis for Restoring and Enhancing Memory Function; Brain Dynamics of Human Motor Control: Neuromorphic Modeling and Brain-Machine-Body Interfaces; Neuroprosthetic Technologies to Improve Functional Recovery after Neuromotor Disorders; Translational Research Tools for Investigating Neurological Disease; Neural Control and Modulation; Neuromodulation of the Spinal Circuitry to Regain Motor Function after Spinal Cord Injury; Neural Excitation-Driven Musculo-Skeletal Modeling for Rehabilitation Technologies; Brain-Computer Interface based on Visual Modulation; Recording Evoked Potentials during Deep Brain Stimulation; Restoring Useful and Functional Movements with FES is Still a Big Challenge: From Past to Present Some Big Issues; Bioengineered Artificial Retina; MRI Measured Brain Connectivities and Their Applications; Update on TMR with Pattern Recognition for Control of Powered Prostheses; High Resolution Recording and Data Mining in Epileptic Networks; Challenges in Increasing the Resolution and Device Longevity of a Retinal Prosthesis; Novel Approaches in Neural and Rehabilitation Engineering; Development of Biomimetic Cortical Interfaces for the Restoration of Sensorimotor Function; Neuroprostheses for Movement Restoration; Tensor Product Kernels for Multiscale Neural Decoding and Control; Neurally and Ocularly Informed Graph-Based Models for Searching 3D Environments; Towards Model-Based Control in Neural Engineering; Translating Revolutionary Prosthesis to Practical Prosthesis; Are Our Cellular Models Fundamentally Wrong?; and Electrophysiological Biomarkers of Human Epileptogenic Brain.

Published

2013

39. Automated identification of multiple seizure-related and interictal epileptiform event types in the EEG of mice

Author

Armando Manduca, Hee-Sup Shin, Rachel A. Bergstrom, Greg Worrell, Jee Hyun Choi, and Charles L. Howe

Subjects

Video Recording, Wavelet Analysis, Convulsants, Electroencephalography, EEG-fMRI, Machine learning, computer.software_genre, Hippocampus, Sensitivity and Specificity, Severity of Illness Index, Article, 03 medical and health sciences, Automation, Mice, 0302 clinical medicine, Wavelet decomposition, Wavelet, Seizures, Medicine, Animals, Ictal, False Positive Reactions, False Negative Reactions, 030304 developmental biology, Event (probability theory), Observer Variation, 0303 health sciences, Multidisciplinary, Kainic Acid, medicine.diagnostic_test, Behavior, Animal, business.industry, Brain Waves, Mice, Inbred C57BL, Automated algorithm, Female, Artificial intelligence, business, Neuroscience, computer, 030217 neurology & neurosurgery, Algorithms, Automated method

Abstract

Visual scoring of murine EEG signals is time-consuming and subject to low inter-observer reproducibility. The Racine scale for behavioral seizure severity does not provide information about interictal or sub-clinical epileptiform activity. An automated algorithm for murine EEG analysis was developed using total signal variation and wavelet decomposition to identify spike, seizure, and other abnormal signal types in single-channel EEG collected from kainic acid-treated mice. The algorithm was validated on multi-channel EEG collected from γ-butyrolacetone-treated mice experiencing absence seizures. The algorithm identified epileptiform activity with high fidelity compared to visual scoring, correctly classifying spikes and seizures with 99% accuracy and 91% precision. The algorithm correctly identifed a spike-wave discharge focus in an absence-type seizure recorded by 36 cortical electrodes. The algorithm provides a reliable and automated method for quantification of multiple classes of epileptiform activity within the murine EEG and is tunable to a variety of event types and seizure categories.

Published

2013

40. High-frequency oscillations and other electrophysiological biomarkers of epilepsy: clinical studies

Author

Jean Gotman and Greg Worrell

Subjects

Clinical Biochemistry, Electroencephalography, EEG-fMRI, Hippocampus, Article, Epilepsy, Seizures, Drug Discovery, Medicine, Humans, Ictal, Epilepsy surgery, medicine.diagnostic_test, business.industry, Biochemistry (medical), Brain, medicine.disease, Electrophysiology, Potential biomarkers, Anesthesia, Biomarker (medicine), business, Neuroscience, Biomarkers

Abstract

Accurate localization of epileptogenic brain is critical for successful epilepsy surgery. Recent research using wide bandwidth intracranial EEG has demonstrated that interictal high-frequency oscillations are preferentially localized to the brain region generating spontaneous seizures, and are a potential biomarker of epileptogenic brain. The existence of an interictal, electrophysiological biomarker of epileptogenic brain has the potential to significantly advance epilepsy surgery by improving outcomes through improved localization and potentially eliminating the reliance on chronic intracranial EEG monitoring.

Published

2011

41. High-Frequency Oscillations in Epileptic Brain

Author

S Stead, Mark Bower, and Greg Worrell

Published

2010

42. Seizures in Organ Transplant Recipients

Author

Tarek Zakaria, Greg Worrell, and Eelco F. M. Wijdicks

Subjects

Pediatrics, medicine.medical_specialty, Chemotherapy, business.industry, Incidence (epidemiology), medicine.medical_treatment, Immunosuppression, Disease, Organ transplantation, Transplantation, surgical procedures, operative, medicine, Tissue trauma, business, Cerebral dysfunction

Abstract

Seizures are a nonspecific neurological manifestation of cerebral dysfunction and are not indicative of any particular disease processes or pathology. Thus, the evaluation and treatment of seizures in transplant patients generally follows the same clinical approach used for other patients. A seizure in a transplant patient is commonly unanticipated and entirely unexplained. The effects can be substantial, with aspiration, loss of vascular catheters, and tissue trauma. Patients undergoing organ transplantation are at risk for seizures for multiple reasons, and although much of the neurological and transplantation literature reports on the incidence of seizures according to the particular organ transplanted (Table 1), there are many similarities (e.g., immunosuppression drugs). This chapter concentrates on organ transplantation as a whole.

Published

2009

43. Removal of Scalp Reference Signal and Line Noise for Intracranial EEGs

Author

Greg Worrell, Sanqing Hu, and Matt Stead

Subjects

Signal processing, medicine.diagnostic_test, Computer science, business.industry, Pattern recognition, Electroencephalography, Blind signal separation, Signal, Independent component analysis, medicine.anatomical_structure, Scalp, medicine, Epilepsy surgery, Artificial intelligence, business, Independence (probability theory)

Abstract

Cephalic references are widely used to record Electroencephalography (EEG). The effect of an active common reference on the recorded EEG is one of the oldest technical problems in the study of EEG. Moreover, in many cases EEG channel recordings are contaminated to different degrees with line noise that can pose a significant problem for EEG interpretation and analysis. Thus, identification and removal of the reference signal and line noise is of importance. Here we apply independent component analysis (ICA) and principle component analysis (PCA) to intracranial recordings and propose three methods to remove the reference signal and line noise based on the assumption that the scalp reference and line noise are independent from the local and distributed intracranial sources. The assumption of independence between the scalp reference and intracranial sources is generally valid because the reference scalp electrode is relatively electrically isolated from the intracranial electrodes by the skull's high resistivity and supported by our previous simulation results [4]. The assumption of independence between the line noise and intracranial sources is definitely true. We apply the three proposed methods to intracranial EEGs from one patient undergoing evaluation for epilepsy surgery, and compare the results to bipolar, average, and notch filter iEEGs.

Published

2008

44. Human and Automated Detection of High-Frequency Oscillations in Clinical Intracranial EEG Recordings

Author

Brian Litt, Andrew B. Gardner, Greg Worrell, Dennis J. Dlugos, and Eric D. Marsh

Subjects

Computer science, Electroencephalography, Stereoelectroencephalography, Article, Neurosurgical Procedures, Consistency (statistics), Physiology (medical), medicine, Humans, Set (psychology), Epilepsy, medicine.diagnostic_test, business.industry, Detector, Reproducibility of Results, Pattern recognition, Intracranial eeg, Sensory Systems, Electrodes, Implanted, Identification (information), Neurology, Data Interpretation, Statistical, Neurology (clinical), Artificial intelligence, business, Neuroscience, Algorithms, Software, Test data

Abstract

Objective Recent studies indicate that pathologic high-frequency oscillations (HFOs) are signatures of epileptogenic brain. Automated tools are required to characterize these events. We present a new algorithm tuned to detect HFOs from 30 to 85Hz, and validate it against human expert electroencephalographers. Methods We randomly selected 28 3-min single-channel epochs of intracranial EEG (IEEG) from two patients. Three human reviewers and three automated detectors marked all records to identify candidate HFOs. Subsequently, human reviewers verified all markings. Results A total of 1330 events were collectively identified. The new method presented here achieved 89.7% accuracy against a consensus set of human expert markings. A one-way ANOVA determined no difference between the mean F -measures of the human reviewers and automated algorithm. Human κ statistics (mean κ =0.38) demonstrated marginal identification consistency, primarily due to false negative errors. Conclusions We present an HFO detector that improves upon existing algorithms, and performs as well as human experts on our test data set. Validation of detector performance must be compared to more than one expert because of interrater variability. Significance This algorithm will be useful for analyzing large EEG databases to determine the pathophysiological significance of HFO events in human epileptic networks.

Published

2007

45. High-frequency oscillations detected in epileptic networks using swarmed neural-network features

Author

Otis Smart, Brian Litt, Greg Worrell, Hiram Firpi, Eric D. Marsh, and Dennis J. Dlugos

Subjects

Adult, Periodicity, Computer science, Feature extraction, Models, Neurological, Biomedical Engineering, Machine learning, computer.software_genre, Pattern Recognition, Automated, Epilepsy, Signal-to-noise ratio, Oscillometry, medicine, Humans, Epilepsy surgery, In patient, Brain Mapping, Artificial neural network, business.industry, Pattern recognition, Electroencephalography, medicine.disease, Intracranial eeg, Electrodes, Implanted, Child, Preschool, Data Interpretation, Statistical, Refractory epilepsy, Artificial intelligence, Nerve Net, business, computer, Algorithms

Abstract

Localizing epileptic networks is a central challenge in guiding epilepsy surgery, deploying antiepileptic devices, and elucidating mechanisms underlying seizure generation. Recent work from our group and others suggests that high-frequency epileptic oscillations (HFEOs) arise from brain regions constituting epileptic networks, and may be important to seizure generation. HFEOs are brief 50–500 Hz pathologic events measured in intracranial field and unit recordings in patients with refractory epilepsy. They are challenging to detect due to low signal to noise ratio, and because they occur in multiple channels with great frequency. Their morphology is also variable and changes with distance from intracranial electrode contacts, which are sparsely placed for patient safety. Thus reliable, automated methods to detect HFEOs are required to localize and track seizure generation in epileptic networks. We present a novel method for mapping the temporal evolution of these oscillations in human epileptic networks. The technique combines a particle swarm optimization algorithm with a neural network to create features that robustly detect and track HFEOs in human intracranial EEG (IEEG) recordings. We demonstrate the algorithm’s performance on IEEG data from six patients, one pediatric and five adult, and compare it to an existing method for detecting high-frequency oscillations.

Published

2006

46. Automatic Detection of High Frequency Epileptiform Oscillations from Intracranial EEG Recordings of Patients with Neocortical Epilepsy

Author

Otis Smart, Brian Litt, Greg Worrell, and George Vachtsevanos

Subjects

Epilepsy, Patient diagnosis, medicine.diagnostic_test, medicine, Epilepsy treatment, Spatial localization, Electroencephalography, medicine.disease, Psychology, Intracranial eeg, Neuroscience, Neocortical epilepsy

Abstract

High frequency epileptiform oscillations (HFEOs) have been observed before neocortical seizures on intracranial EEG recordings. There is suggestion that HFEOs may localize epileptic brain regions important to seizure generation in humans, a finding that would be valuable for understanding, diagnosing, and treating epilepsy. In this paper, an automated approach for detecting HFEOs is described. Fuzzy clustering and histograms are used to characterize HFEO events. Compared to neurologist markings, the algorithm detected 87% of the HFEOs while achieving 68% precision and 90% specificity, without training. Applied to thirty-five minute seizure records obtained from six patients, spatial and temporal localization of HFEOs were observed in 77% and 61% of the segments respectively. Results highlight the potential of the method to identify brain regions vital to seizure generation by tracking the spatio-temporal evolution of high frequency seizure precursors in the epileptic network.

Published

2006

47. Continuous energy variation during the seizure cycle: towards an on-line accumulated energy

Author

Javier Echauz, Brian Litt, M. D'Alessandro, Greg Worrell, Rosana Esteller, Steve Cranstoun, and George Vachtsevanos

Subjects

medicine.medical_specialty, Time Factors, Entropy, Audiology, Electroencephalography, Stereoelectroencephalography, Article, Epilepsy, Predictive Value of Tests, Seizures, Physiology (medical), Prediction methods, medicine, Humans, Ictal, Entropy (energy dispersal), Retrospective Studies, medicine.diagnostic_test, Signal Processing, Computer-Assisted, medicine.disease, Sensory Systems, Neurology, Energy variation, Neurology (clinical), Epileptic seizure, medicine.symptom, Psychology, Neuroscience, Algorithms

Abstract

Increases in accumulated energy on intracranial EEG are associated with oncoming seizures in retrospective studies, supporting the idea that seizures are generated over time. Published seizure prediction methods require comparison to 'baseline' data, sleep staging, and selecting seizures that are not clustered closely in time. In this study, we attempt to remove these constraints by using a continuously adapting energy threshold, and to identify stereotyped energy variations through the seizure cycle (inter-, pre-, post- and ictal periods).Accumulated energy was approximated by using moving averages of signal energy, computed for window lengths of 1 and 20 min, and an adaptive decision threshold. Predictions occurred when energy within the shorter running window exceeded the decision threshold.Predictions for time horizons of less than 3h did not achieve statistical significance in the data sets analyzed that had an average inter-seizure interval ranging from 2.9 to 8.6h. 51.6% of seizures across all patients exhibited stereotyped pre-ictal energy bursting and quiet periods.Accumulating energy alone is not sufficient for predicting seizures using a 20 min running baseline for comparison. Stereotyped energy patterns through the seizure cycle may provide clues to mechanisms underlying seizure generation.Energy-based seizure prediction will require fusion of multiple complimentary features and perhaps longer running averages to compensate for post-ictal and sleep-induced energy changes.

Published

2004

48. Erratum

Author

Kevin E. Bennet, Steven J. Goerss, Matt Stead, Greg Worrell, Su Youne Chang, J. J. Van Gompel, Mark R. Bower, W. R. Marsh, Charles D. Blaha, Inyong Kim, F. B. Meyer, and Kendall H. Lee

Subjects

medicine.medical_specialty, Endocrinology, Neurology, Chemistry, Anesthesia, Internal medicine, medicine, Extracellular, Neurology (clinical), Adenosine, medicine.drug

Published

2014

49. Ovarian hyperstimulation syndrome with ischemic stroke due to an intracardiac thrombus

Author

Scott D.Z. Eggers, C. J. Mullany, M. A. Damario, Greg Worrell, Eelco F. M. Wijdicks, and Thanh G. Phan

Subjects

Adult, medicine.medical_specialty, medicine.medical_treatment, Ovarian hyperstimulation syndrome, Human chorionic gonadotropin, Brain Ischemia, Ovarian Hyperstimulation Syndrome, medicine, Coagulopathy, Humans, Thrombus, Stroke, In vitro fertilisation, business.industry, Coronary Thrombosis, medicine.disease, Magnetic Resonance Imaging, Surgery, Venous thrombosis, Embolism, Echocardiography, Anesthesia, Female, Neurology (clinical), business

Abstract

Ovarian hyperstimulation syndrome (OHSS) is a rare complication in patients undergoing ovarian induction therapy.1 The clinical symptoms include nausea, vomiting, abdominal and pleural effusions, and ovarian enlargement. Hemoconcentration, owing to the large fluid shifts from the intravascular space to the peritoneal cavity, results in increased blood viscosity and sometimes a coagulopathy that can lead to arterial and venous occlusions. Thromboembolic stroke,1-3⇓⇓ cerebral venous thrombosis,4 and systemic arteriovenous thrombosis5 have been reported in OHSS. We describe a young woman who developed OHSS after in vitro fertilization and subsequently had an embolic stroke from an intracardiac thrombus. A 34-year-old right-handed woman underwent in vitro fertilization–embryo transfer treatment. The standard stimulation protocol included pituitary downregulation with injections of the gonadotropin-releasing hormone agonist leuprolide, followed by recombinant follicle-stimulating hormone. Peak serum estradiol level was 2,852 pg/mL, at which time human chorionic gonadotropin was given intramuscularly. Oocyte retrieval was followed by daily intramuscular progesterone administration and oocyte fertilization. Two embryos were transferred 2 days after oocyte retrieval. Seven days later, she was hospitalized with symptoms …

Published

2001

50. 86. Group analysis of interictal SPECT images in patients with mesial TLE demonstrates ipsilateral temporal lobe hyperperfusion

Author

Noojan Kazemi, Elson L. So, Terence J. O'Brien, Squire M. Stead, Greg Worrell, and Ben Brinkmann

Subjects

Neurology, Group analysis, business.industry, Physiology (medical), Medicine, Surgery, Ictal, In patient, Neurology (clinical), General Medicine, Nuclear medicine, business, Temporal lobe

Published

2010