2022
331 Role of Functional Network Formation in Epilepsy
Boddeti U, Bachani M, Moyer M, Owotade J, Serra R, Zaveri H, Ksendzovsky A. 331 Role of Functional Network Formation in Epilepsy. Neurosurgery 2022, 68: 75-76. DOI: 10.1227/neu.0000000000001880_331.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsEpileptogenic focusFocal epilepsyTetanic stimulationGood surgical outcomePrimary mixed culturesMulti-electrode arraysCortical epilepsyRefractory seizuresSurgical resectionSurgical outcomesEpileptogenic networksVitro stimulationCortical neuronsRat pupsSeizure onsetAxonal boutonsEpilepsy patientsSurgery decisionDaily stimulationDendritic spinesSeizure formationEpilepsyVitro modelStimulationNetwork disorder
2021
Increased branched‐chain amino acids at baseline and hours before a spontaneous seizure in the human epileptic brain
Ong C, Damisah EC, Gruenbaum SE, Dhaher R, Deng Y, Sandhu MRS, Zaveri HP, Spencer DD, Eid T. Increased branched‐chain amino acids at baseline and hours before a spontaneous seizure in the human epileptic brain. Epilepsia 2021, 62: e88-e97. PMID: 33949690, PMCID: PMC11259155, DOI: 10.1111/epi.16920.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAdultAmino Acids, Branched-ChainBrain ChemistryChildChild, PreschoolChromatography, High Pressure LiquidDrug Resistant EpilepsyElectrocorticographyElectroencephalographyEpilepsies, PartialExtracellular SpaceFemaleGlutamic AcidHumansIsoleucineMaleMicrodialysisMiddle AgedSeizuresTandem Mass SpectrometryYoung AdultConceptsSpontaneous seizuresDrug-resistant focal epilepsyExtracellular brain glutamateHuman epileptic brainBranched-chain amino acidsBranched chain amino acids valineRefractory epilepsyBrain microdialysisGlutamatergic neurotransmissionFocal epilepsySeizure onsetBrain glutamateEpileptic brainHuman patientsSeizuresBrain regionsDialysis samplesMammalian targetEpilepsyLiquid chromatography-tandem mass spectrometryBaselineBCAAIntracranial electroencephalographyChromatography-tandem mass spectrometryPatientsNetwork-Related Changes in Neurotransmitters and Seizure Propagation During Rodent Epileptogenesis
Dhaher R, Gruenbaum SE, Sandhu MRS, Ottestad-Hansen S, Tu N, Wang Y, Lee TW, Deshpande K, Spencer DD, Danbolt NC, Zaveri HP, Eid T. Network-Related Changes in Neurotransmitters and Seizure Propagation During Rodent Epileptogenesis. Neurology 2021, 96: e2261-e2271. PMID: 33722994, PMCID: PMC8166437, DOI: 10.1212/wnl.0000000000011846.Peer-Reviewed Original ResearchConceptsSpontaneous seizuresSeizure propagationSeizure focusMesial temporal lobe epilepsyExtracellular brain levelsTemporal lobe epilepsyExtracellular glutamate levelsRelevant rodent modelsGlutamine synthetase inhibitor methionine sulfoximineTransporter subtype 1Contralateral hippocampusLobe epilepsyBrain levelsBrain microdialysisExtracellular GABANeurotransmitter levelsSeizure initiationGlutamate levelsSeizure onsetEpilepsy networkRodent modelsSubtype 1EpileptogenesisHippocampusBrain regions
2018
Resting state connectivity in neocortical epilepsy: The epilepsy network as a patient-specific biomarker
Marino AC, Yang GJ, Tyrtova E, Wu K, Zaveri HP, Farooque P, Spencer DD, Bandt SK. Resting state connectivity in neocortical epilepsy: The epilepsy network as a patient-specific biomarker. Clinical Neurophysiology 2018, 130: 280-288. PMID: 30605890, DOI: 10.1016/j.clinph.2018.11.016.Peer-Reviewed Original ResearchConceptsLocalization related epilepsyEpilepsy networkSeizure onset locationSingle-patient levelCorrelated network activityPatient-specific biomarkersRelated epilepsyConnectivity patternsNeocortical epilepsyPatient levelSeizure onsetInterictal periodAnatomic locationPatientsPossible biomarkersState connectivityCortical regionsSingle-subject levelTopographic distributionCohortNetwork disorderBrain networksEpilepsyNetwork activityBiomarkersExpanding Brain–Computer Interfaces for Controlling Epilepsy Networks: Novel Thalamic Responsive Neurostimulation in Refractory Epilepsy
Gummadavelli A, Zaveri HP, Spencer DD, Gerrard JL. Expanding Brain–Computer Interfaces for Controlling Epilepsy Networks: Novel Thalamic Responsive Neurostimulation in Refractory Epilepsy. Frontiers In Neuroscience 2018, 12: 474. PMID: 30108472, PMCID: PMC6079216, DOI: 10.3389/fnins.2018.00474.Peer-Reviewed Original ResearchResponsive neurostimulationRefractory epilepsyThalamic nucleiComplex network disorderIntralaminar thalamic nucleiSubcortical brain structuresCortical onsetSeizure controlGeneralized epilepsySeizure networkSeizure onsetEpilepsy networkNeuromodulatory techniquesEpilepsyExcitatory eventsClinical treatmentBrain regionsBrain structuresSeizuresPotential targetIntracranial electroencephalographyNetwork disorderPatientsFeasible targetNeurostimulation
2014
The spatial and signal characteristics of physiologic high frequency oscillations
Alkawadri R, Gaspard N, Goncharova II, Spencer DD, Gerrard JL, Zaveri H, Duckrow RB, Blumenfeld H, Hirsch LJ. The spatial and signal characteristics of physiologic high frequency oscillations. Epilepsia 2014, 55: 1986-1995. PMID: 25470216, PMCID: PMC5123742, DOI: 10.1111/epi.12851.Peer-Reviewed Original ResearchConceptsPhysiologic high-frequency oscillationsSeizure onsetEpileptic networkNon-rapid eye movement sleepComprehensive Epilepsy CenterMesial temporal structuresEye movement sleepHighest HFO ratesHigh-frequency oscillationsFirst seizureInvasive evaluationEpilepsy centersIntracranial evaluationMovement sleepPerirolandic regionEpileptiform dischargesParietooccipital regionOccipital lobeEpileptic sitesPatientsNonepileptic regionsPhysiologic eventsFast ripplesHFO ratesLonger duration
2013
Seizure localization using three-dimensional surface projections of intracranial EEG power
Lee HW, Youngblood MW, Farooque P, Han X, Jhun S, Chen WC, Goncharova I, Vives K, Spencer DD, Zaveri H, Hirsch LJ, Blumenfeld H. Seizure localization using three-dimensional surface projections of intracranial EEG power. NeuroImage 2013, 83: 616-626. PMID: 23850575, PMCID: PMC3815983, DOI: 10.1016/j.neuroimage.2013.07.010.Peer-Reviewed Original ResearchConceptsEpilepsy surgerySeizure localizationGood surgical outcomeEEG powerIntractable epilepsy patientsAgreement rateNormal brain functionOverall agreement ratePoor outcomeSurgical outcomesIntractable epilepsyIcEEG recordingsSeizure onsetSublobar localizationEpilepsy patientsIndependent reviewersClinical informationIcEEG dataPatientsBrain functionSurgeryImproved diagnostic methodIntracranial EEGDiagnostic methodsOutcomes
2009
Spatial distribution of intracranially recorded spikes in medial and lateral temporal epilepsies
Goncharova II, Zaveri HP, Duckrow RB, Novotny EJ, Spencer SS. Spatial distribution of intracranially recorded spikes in medial and lateral temporal epilepsies. Epilepsia 2009, 50: 2575-2585. PMID: 19674048, DOI: 10.1111/j.1528-1167.2009.02258.x.Peer-Reviewed Original ResearchConceptsMedial temporal structuresInterictal spikesLT patientsCortical areasNeocortical seizure onsetsSleep-related increaseSpike rateLateral temporal epilepsyExtratemporal areasTemporal epilepsySeizure onsetIntracranial monitoringLT groupMT groupPatientsFrontal spikesSeizuresGreater numberSleepGroupTemporal structureEpilepsySpikes
2008
Interictal spikes on intracranial recording: Behavior, physiology, and implications
Spencer SS, Goncharova II, Duckrow RB, Novotny EJ, Zaveri HP. Interictal spikes on intracranial recording: Behavior, physiology, and implications. Epilepsia 2008, 49: 1881-1892. PMID: 18479398, DOI: 10.1111/j.1528-1167.2008.01641.x.Peer-Reviewed Original ResearchConceptsInterictal spikesAED withdrawalSeizure onsetSpike rateMedial temporal lobe seizuresAntiepileptic drug changesRefractory epileptic patientsTemporal lobe seizuresOnset seizuresDrug changesEpileptic patientsNeocortical locationsClinical meaningMedial temporalSeizuresIntracranial electrodesDays of recordingAED mechanismsIntracranial recordingsSignificant increaseAEDsPrevious reportsOnsetSpecific effectsWithdrawal
2001
Distinguishing Subtypes of Temporal Lobe Epilepsy with Background Hippocampal Activity
Zaveri H, Duckrow R, De Lanerolle N, Spencer S. Distinguishing Subtypes of Temporal Lobe Epilepsy with Background Hippocampal Activity. Epilepsia 2001, 42: 725-730. PMID: 11422326, DOI: 10.1046/j.1528-1157.2001.00500.x.Peer-Reviewed Original ResearchConceptsMesial temporal sclerosisTemporal lobe epilepsyLobe epilepsySurgical outcomesIntractable temporal lobe epilepsyPoor surgical outcomesGood surgical outcomeMedial temporal structuresMedial temporal lobeDelta band powerTemporal sclerosisRetrospective studyHippocampal tissueBackground EEGSeizure onsetIndividual patientsSurgical proceduresIntracranial monitoringTemporal lobeGamma frequency bandClinical observationsPatientsAnterior hippocampusCell lossSubtypes