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42 results on '"Scheuer, Mark L"'

1. Optical Flow Estimation Improves Automated Seizure Detection in Neonatal EEG

Author

Martin, Joel R, Gabriel, Paolo G, Gold, Jeffrey J, Haas, Richard, Davis, Suzanne L, Gonda, David D, Sharpe, Cynthia, Wilson, Scott B, Nierenberg, Nicolas C, Scheuer, Mark L, and Wang, Sonya G

Subjects
Paediatrics, Biomedical and Clinical Sciences, Brain Disorders, Bioengineering, Neurodegenerative, Neurosciences, Epilepsy, Pediatric, Algorithms, Artifacts, Electroencephalography, Humans, Infant, Newborn, Optic Flow, Seizures, Electroencephalogram, Epilepsy monitoring, Seizure, Neonatal, Seizure detection, Optical flow, Computer vision, Clinical Sciences, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology, Clinical and health psychology
Abstract

PurposeExisting automated seizure detection algorithms report sensitivities between 43% and 77% and specificities between 56% and 90%. The algorithms suffer from false alarms when applied to neonatal EEG because of the high degree of nurse handling and rhythmic patting used to soothe neonates. Computer vision technology that quantifies movement in real time could distinguish artifactual motion and improve automated neonatal seizure detection algorithms.MethodsThe authors used video EEG recordings from 43 neonates undergoing monitoring for seizures as part of the NEOLEV2 clinical trial. The Persyst neonatal automated seizure detection algorithm ran in real time during study EEG acquisitions. Computer vision algorithms were applied to extract detailed accounts of artifactual movement of the neonate or people near the neonate though dense optical flow estimation.ResultsUsing the methods mentioned above, 197 periods of patting activity were identified and quantified, of which 45 generated false-positive automated seizure detection events. A binary patting detection algorithm was trained with a subset of 470 event videos. This supervised detection algorithm was applied to a testing subset of 187 event videos with 8 false-positive events, which resulted in a 24% reduction in false-positive automated seizure detections and a 50% reduction in false-positive events caused by neonatal care patting, while maintaining 11 of 12 true-positive seizure detection events.ConclusionsThis work presents a novel approach to improving automated seizure detection algorithms used during neonatal video EEG monitoring. This artifact detection mechanism can improve the ability of a seizure detector algorithm to distinguish between artifact and true seizure activity.

Published
2022

8. Quantitative EEG predicting acute neurological deterioration in the pediatric ICU: a case series

Author

Munjal, Neil K., Bergman, Ira, Scheuer, Mark L., Genovese, Christopher R., Simon, Dennis W., and Patterson, Christina M.

Subjects
Adult, Male, Adolescent, Critical Care, Critical Illness, Infant, Electroencephalography, Intensive Care Units, Pediatric, Article, Young Adult, Evaluation Studies as Topic, Predictive Value of Tests, Child, Preschool, Acute Disease, Humans, Female, Nervous System Diseases, Child
Abstract

INTRODUCTION: Continuous neurological assessment in the pediatric intensive care unit (PICU) is challenging. Current electroencephalography (EEG) guidelines support monitoring status epilepticus, vasospasm detection, and cardiac arrest prognostication, but the scope of brain dysfunction in critically-ill patients is larger. We explore quantitative electroencephalography (QEEG) in PICU patients with neurological emergencies to identify QEEG changes preceding clinical detection. METHODS: From 2017 to 2020, we identified PICU patients at a single quaternary children’s hospital with EEG recording near or during acute neurological deterioration. QEEG analysis was performed using Persyst P14 (Persyst Development Corporation). Included features were FFT, asymmetry, and rhythmicity spectrograms, “from-baseline” patient-specific versions of above features, and quantitative suppression ratio. Timing of QEEG changes was determined by expert review and prespecified QEEG alert thresholds. Clinical detection of neurologic deterioration was defined pre-hoc and determined by Electronic Medical Record documentation of exam change or intervention. RESULTS: 10 patients were identified, age 23 months to 27 years, 50% female. Of 10 patients, 6 died, 1 had new morbidity, and 3 had good recovery; the most common cause of death was cerebral edema and herniation. The fastest changes were on “from-baseline” FFT spectrograms, while persistent changes on asymmetry spectrograms and suppression ratio were most associated with morbidity and mortality. Median time from first QEEG change to clinical detection was 332 min (Interquartile range: 201 -- 456 min). CONCLUSION: Quantitative EEG is potentially useful in earlier detection of neurological deterioration in critically-ill PICU patients. Further work is required to quantify the predictive value, measure improvement in outcome, and automate the process.

Published
2021

12. Quantitative Electroencephalography (EEG) Predicting Acute Neurologic Deterioration in the Pediatric Intensive Care Unit: A Case Series.

Author

Munjal, Neil K., Bergman, Ira, Scheuer, Mark L., Genovese, Christopher R., Simon, Dennis W., and Patterson, Christina M.

Subjects
PEDIATRIC intensive care, INTENSIVE care units, INTENSIVE care patients, FAST Fourier transforms, ELECTROENCEPHALOGRAPHY, EPILEPSY
Abstract

Introduction: Continuous neurologic assessment in the pediatric intensive care unit is challenging. Current electroencephalography (EEG) guidelines support monitoring status epilepticus, vasospasm detection, and cardiac arrest prognostication, but the scope of brain dysfunction in critically ill patients is larger. We explore quantitative EEG in pediatric intensive care unit patients with neurologic emergencies to identify quantitative EEG changes preceding clinical detection. Methods: From 2017 to 2020, we identified pediatric intensive care unit patients at a single quaternary children's hospital with EEG recording near or during acute neurologic deterioration. Quantitative EEG analysis was performed using Persyst P14 (Persyst Development Corporation). Included features were fast Fourier transform, asymmetry, and rhythmicity spectrograms, "from-baseline" patient-specific versions of the above features, and quantitative suppression ratio. Timing of quantitative EEG changes was determined by expert review and prespecified quantitative EEG alert thresholds. Clinical detection of neurologic deterioration was defined pre hoc and determined through electronic medical record documentation of examination change or intervention. Results: Ten patients were identified, age 23 months to 27 years, and 50% were female. Of 10 patients, 6 died, 1 had new morbidity, and 3 had good recovery; the most common cause of death was cerebral edema and herniation. The fastest changes were on "from-baseline" fast Fourier transform spectrograms, whereas persistent changes on asymmetry spectrograms and suppression ratio were most associated with morbidity and mortality. Median time from first quantitative EEG change to clinical detection was 332 minutes (interquartile range: 201-456 minutes). Conclusion: Quantitative EEG is potentially useful in earlier detection of neurologic deterioration in critically ill pediatric intensive care unit patients. Further work is required to quantify the predictive value, measure improvement in outcome, and automate the process. [ABSTRACT FROM AUTHOR]

Published
2022
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19. The evaluation and treatment of seizures

Author

Scheuer, Mark L. and Pedley, Timothy A.

Subjects
Epilepsy -- Care and treatment, Anticonvulsants -- Evaluation, Epileptics -- Health aspects, Electroencephalography, Febrile convulsions -- Care and treatment
Published
1990

28. The ACNS Subcommittee on Research Terminology for Continuous EEG Monitoring: Proposed Standardized Terminology for Rhythmic and Periodic EEG Patterns Encountered in Critically Ill Patients

Author

Hirsch, Lawrence J., primary, Brenner, Richard P., additional, Drislane, Frank W., additional, So, Elson, additional, Kaplan, Peter W., additional, Jordan, Kenneth G., additional, Herman, Susan T., additional, LaRoche, Suzette M., additional, Young, Bryan, additional, Bleck, Thomas P., additional, Scheuer, Mark L., additional, and Emerson, Ronald G., additional

Published
2005
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30. Analysis of Multi-Channel Subdural EEG by Recurrent Neural Networks.

Author

Zimmermann, Hans-Jürgen, Attoh-Okine, Nii O., Ayyub, Bilal M., Bates, Robyn R., Sun, Mingui, Scheuer, Mark L., and Sclabassi, Robert J.

Abstract

It was shown that recurrent neural networks with relatively simple architectures are capable of detecting seizure-like activity in multi-channel EEG records. Furthermore, the results obtained from the three different architectures studied were fairly consistent in locating the generators of seizure-like activity based on the patient's subdural EEG montage. If these results are verified by other studies, then these neural networks may serve as effective functional engines in more sophisticated seizure detection utilities. Additional work to increase the detection ability of these networks needs to be undertaken, especially with regard to the separation of the EEG data recorded at each electrode. Also, a means by which a utility using these neural networks can be made more adaptive to a variety of seizures from a wide patient population needs to be examined. [ABSTRACT FROM AUTHOR]

Published
2005
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35. REPLY

Author

Walczak, Thaddeus S., primary, Williams, Daniel T., additional, and Scheuer, Mark L., additional

Published
1996
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37. Localization of a gene for partial epilepsy to chromosome 10q

Author

Ottman, Ruth, primary, Risch, Neil, additional, Hauser, W. Allen, additional, Pedley, Timothy A., additional, Lee, Joseph H., additional, Barker-Cummings, Christie, additional, Lustenberger, Anita, additional, Nagle, Keith J., additional, Lee, Kyusang S., additional, Scheuer, Mark L., additional, Neystat, Michael, additional, Susser, Mervyn, additional, and Wilhelmsen, Kirk C., additional

Published
1995
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39. Seizures and Epilepsy in the Elderly

Author

Scheuer, Mark L. and Cohen, Jeffrey

Abstract

Recent data indicate that the incidence and prevalence of seizures and epilepsy rise substantially in the elderly. Little well-founded information is available on which to base treatment decisions. This article discusses cause, diagnostic evaluation, and antiepileptic drug pharmacology. Tentative treatment suggestions are offered, emphasizing the limits of available knowledge.

Published
1993
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41. Spike separation from EEG/MEG data using morphological filter and wavelet transform.

Author

Jia W, Sclabassi RJ, Pon LS, Scheuer ML, and Sun M

Subjects
Algorithms, Artifacts, Brain Mapping, Computer Simulation, Diagnosis, Computer-Assisted, Electroencephalography methods, Epilepsy diagnosis, Humans, Magnetoencephalography methods, Models, Theoretical, Neural Networks, Computer, Principal Component Analysis, Signal Processing, Computer-Assisted, Software, Time Factors, Electroencephalography instrumentation, Magnetoencephalography instrumentation
Abstract

In the analysis of epileptic electroencephalographic (EEG) and magnetoencephalography (MEG) data, spike separation is diagnostically important because localization of epileptic focus often depends on accurate extraction of spiky activity from the raw data. In this paper, we present a method to automatically extract spikes using the wavelet transform combined with morphological filtering based on a circular structuring element. Our experimental results have shown that this method is highly effective in spike separation. Comparisons with the wavelet, bandpass filter, empirical mode decomposition (EMD), and independent component analysis (ICA) methods show that the new method is more effective in estimating both spike amplitudes and locations.

Published
2006
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42. Data analysis for continuous EEG monitoring in the ICU: seeing the forest and the trees.

Author

Scheuer ML and Wilson SB

Subjects
Computer Graphics, Humans, Intensive Care Units organization & administration, Statistics as Topic methods, Algorithms, Critical Care methods, Diagnosis, Computer-Assisted, Electroencephalography methods, Seizures diagnosis, Signal Processing, Computer-Assisted, User-Computer Interface
Abstract

Continuous EEG monitoring (CEEG) is a powerful tool for evaluating cerebral function in obtunded and comatose critically ill patients. The ongoing analysis of CEEG data is a major task because of the volume of data generated during monitoring and the need for near real-time interpretation of a patient's EEG patterns. Advances in digital EEG data acquisition, computer processing, data transmission, and data display have made CEEG monitoring in the intensive care unit technically feasible. A variety of quantitative EEG tools such as Fourier analysis and amplitude-integrated EEG, and other methods of data analysis such as computerized seizure detection, increasingly allow for focused review of EEG epochs of potential interest. These tools reduce the tremendous time burdens that accompany analysis of the complete CEEG data stream, and allow bedside personnel and nonexpert staff to potentially recognize significant EEG changes in a timely fashion. This article uses literature review and clinical case examples to illustrate techniques for the display and analysis of intensive care unit CEEG recordings. Areas requiring further research and development are discussed.

Published
2004

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