Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes

Massimo Rizzi; Claudia Brandt; Itai Weissberg; Dan Z. Milikovsky; Alberto Pauletti; Gaetano Terrone; Alessia Salamone; Federica Frigerio; Wolfgang Löscher; Alon Friedman; Annamaria Vezzani

doi:10.1016/j.nbd.2018.12.014

Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes

Massimo Rizzi, Claudia Brandt, Itai Weissberg, Dan Z. Milikovsky, Alberto Pauletti, Gaetano Terrone, Alessia Salamone, Federica Frigerio, Wolfgang Löscher, Alon Friedman, Annamaria Vezzani

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

The lack of early biomarkers of epileptogenesis precludes a sound prediction of epilepsy development after acute brain injuries and of the natural course of the disease thus impairing the development of antiepileptogenic treatments. We investigated whether the dimensional changes of nonlinear dynamics in EEG/ECoG signals, that were recorded in the early aftermath of different epileptogenic injuries, provide a measure to be exploited as a sensitive prognostic and predictive biomarker for epilepsy. Using three different models of epilepsy in two rodent species, we report a common and significant decrease of nonlinear dynamics dimension in EEG/ECoG tracings during early epileptogenesis. In particular, the magnitude of this dimensional decrease predicts the severity of ensuing epilepsy, and this measure is modulated by disease-modifying or antiepileptogenic treatments. The broad application of EEG/ECoG monitoring in epilepsy underlines the translational value of these findings for enriching the population of patients at risk for developing epilepsy in clinical investigations.

Original language	English
Pages (from-to)	373-378
Number of pages	6
Journal	Neurobiology of Disease
Volume	124
DOIs	https://doi.org/10.1016/j.nbd.2018.12.014
State	Published - 1 Apr 2019

Keywords

Animal models of epilepsy
Biomarker
Disease modification treatments
Recurrence quantification analysis

ASJC Scopus subject areas

Neurology

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10.1016/j.nbd.2018.12.014

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Rizzi, Massimo ; Brandt, Claudia ; Weissberg, Itai ; Milikovsky, Dan Z. ; Pauletti, Alberto ; Terrone, Gaetano ; Salamone, Alessia ; Frigerio, Federica ; Löscher, Wolfgang ; Friedman, Alon ; Vezzani, Annamaria. / Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes. In: Neurobiology of Disease. 2019 ; Vol. 124. pp. 373-378.

@article{75e780313370437aba725e33132f01e5,

title = "Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes",

abstract = "The lack of early biomarkers of epileptogenesis precludes a sound prediction of epilepsy development after acute brain injuries and of the natural course of the disease thus impairing the development of antiepileptogenic treatments. We investigated whether the dimensional changes of nonlinear dynamics in EEG/ECoG signals, that were recorded in the early aftermath of different epileptogenic injuries, provide a measure to be exploited as a sensitive prognostic and predictive biomarker for epilepsy. Using three different models of epilepsy in two rodent species, we report a common and significant decrease of nonlinear dynamics dimension in EEG/ECoG tracings during early epileptogenesis. In particular, the magnitude of this dimensional decrease predicts the severity of ensuing epilepsy, and this measure is modulated by disease-modifying or antiepileptogenic treatments. The broad application of EEG/ECoG monitoring in epilepsy underlines the translational value of these findings for enriching the population of patients at risk for developing epilepsy in clinical investigations.",

keywords = "Animal models of epilepsy, Biomarker, Disease modification treatments, Recurrence quantification analysis",

author = "Massimo Rizzi and Claudia Brandt and Itai Weissberg and Milikovsky, {Dan Z.} and Alberto Pauletti and Gaetano Terrone and Alessia Salamone and Federica Frigerio and Wolfgang L{\"o}scher and Alon Friedman and Annamaria Vezzani",

note = "Funding Information: We are grateful to Prof. Charles Webber (Loyola University Chicago, Health Sciences Division, Chicago, USA) who generously provided the source codes of RQA applications. We wish to thank also Dr. Wiebke Theilmann (Department of Pharmacology, Toxicology and Pharmacy, University of Veterinary Medicine, Hannover, Germany) for her contribution to this study.This work used the EGI Applications On Demand Service, which is co-funded by the EGI-Engage project (Horizon 2020) under Grant number 654142. We are grateful to Dr. Giuseppe La Rocca and Dr. Gergely Sipos (Customer and Technical Outreach Managers - The EGI Foundation, Science Park 140 - 1098 XG Amsterdam, The Netherlands) for their crucial technical support related to computational resources. Specifically, this work benefited from services and resources provided by the following Virtual Organizations: fedcloud.egi.eu, supported by the national resource providers of the EGI Federation; biomed, with the dedicated support of resource centers BEINJING-LCG2, IN2P3-IRES, OBSPM, INFN-FERRARA, GARR-01-DIR, INFN-CATANIA, INFN-ROMA3, INFN-BARI, CREATIS-INSA-LYON, NCG-INGRID-PT, INFN-PISA, CESNET-MetaCloud and CLOUFIN, resource centers in UK hosted by GridPP collaboration, and the additional support of the resource centers listed here: http://operations-portal.egi.eu/vapor/resources/GL2Browser?VOfilter=biomed.This work was supported by European Union's Seventh Framework Programme (FP7/2007-2013) under grant agreement n. 602102 (EPITARGET to A.V., A.F., W.L.) and by ARCEM association (M.R.). Funding Information: This work used the EGI Applications On Demand Service, which is co-funded by the EGI-Engage project ( Horizon 2020 ) under Grant number 654142 . We are grateful to Dr. Giuseppe La Rocca and Dr. Gergely Sipos (Customer and Technical Outreach Managers - The EGI Foundation, Science Park 140 - 1098 XG Amsterdam, The Netherlands) for their crucial technical support related to computational resources. Specifically, this work benefited from services and resources provided by the following Virtual Organizations: fedcloud.egi.eu , supported by the national resource providers of the EGI Federation ; biomed, with the dedicated support of resource centers BEINJING-LCG2, IN2P3-IRES, OBSPM, INFN-FERRARA, GARR-01-DIR, INFN-CATANIA, INFN-ROMA3, INFN-BARI, CREATIS-INSA-LYON, NCG-INGRID-PT, INFN-PISA, CESNET-MetaCloud and CLOUFIN, resource centers in UK hosted by GridPP collaboration, and the additional support of the resource centers listed here: http://operations-portal.egi.eu/vapor/resources/GL2Browser?VOfilter=biomed . Funding Information: This work was supported by European Union's Seventh Framework Programme ( FP7/2007-2013 ) under grant agreement n. 602102 (EPITARGET to A.V., A.F., W.L.) and by ARCEM association (M.R.). Publisher Copyright: {\textcopyright} 2018",

year = "2019",

month = apr,

day = "1",

doi = "10.1016/j.nbd.2018.12.014",

language = "English",

volume = "124",

pages = "373--378",

journal = "Neurobiology of Disease",

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Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes. / Rizzi, Massimo; Brandt, Claudia; Weissberg, Itai; Milikovsky, Dan Z.; Pauletti, Alberto; Terrone, Gaetano; Salamone, Alessia; Frigerio, Federica; Löscher, Wolfgang; Friedman, Alon; Vezzani, Annamaria.

In: Neurobiology of Disease, Vol. 124, 01.04.2019, p. 373-378.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes

AU - Rizzi, Massimo

AU - Brandt, Claudia

AU - Weissberg, Itai

AU - Milikovsky, Dan Z.

AU - Pauletti, Alberto

AU - Terrone, Gaetano

AU - Salamone, Alessia

AU - Frigerio, Federica

AU - Löscher, Wolfgang

AU - Friedman, Alon

AU - Vezzani, Annamaria

N1 - Funding Information: We are grateful to Prof. Charles Webber (Loyola University Chicago, Health Sciences Division, Chicago, USA) who generously provided the source codes of RQA applications. We wish to thank also Dr. Wiebke Theilmann (Department of Pharmacology, Toxicology and Pharmacy, University of Veterinary Medicine, Hannover, Germany) for her contribution to this study.This work used the EGI Applications On Demand Service, which is co-funded by the EGI-Engage project (Horizon 2020) under Grant number 654142. We are grateful to Dr. Giuseppe La Rocca and Dr. Gergely Sipos (Customer and Technical Outreach Managers - The EGI Foundation, Science Park 140 - 1098 XG Amsterdam, The Netherlands) for their crucial technical support related to computational resources. Specifically, this work benefited from services and resources provided by the following Virtual Organizations: fedcloud.egi.eu, supported by the national resource providers of the EGI Federation; biomed, with the dedicated support of resource centers BEINJING-LCG2, IN2P3-IRES, OBSPM, INFN-FERRARA, GARR-01-DIR, INFN-CATANIA, INFN-ROMA3, INFN-BARI, CREATIS-INSA-LYON, NCG-INGRID-PT, INFN-PISA, CESNET-MetaCloud and CLOUFIN, resource centers in UK hosted by GridPP collaboration, and the additional support of the resource centers listed here: http://operations-portal.egi.eu/vapor/resources/GL2Browser?VOfilter=biomed.This work was supported by European Union's Seventh Framework Programme (FP7/2007-2013) under grant agreement n. 602102 (EPITARGET to A.V., A.F., W.L.) and by ARCEM association (M.R.). Funding Information: This work used the EGI Applications On Demand Service, which is co-funded by the EGI-Engage project ( Horizon 2020 ) under Grant number 654142 . We are grateful to Dr. Giuseppe La Rocca and Dr. Gergely Sipos (Customer and Technical Outreach Managers - The EGI Foundation, Science Park 140 - 1098 XG Amsterdam, The Netherlands) for their crucial technical support related to computational resources. Specifically, this work benefited from services and resources provided by the following Virtual Organizations: fedcloud.egi.eu , supported by the national resource providers of the EGI Federation ; biomed, with the dedicated support of resource centers BEINJING-LCG2, IN2P3-IRES, OBSPM, INFN-FERRARA, GARR-01-DIR, INFN-CATANIA, INFN-ROMA3, INFN-BARI, CREATIS-INSA-LYON, NCG-INGRID-PT, INFN-PISA, CESNET-MetaCloud and CLOUFIN, resource centers in UK hosted by GridPP collaboration, and the additional support of the resource centers listed here: http://operations-portal.egi.eu/vapor/resources/GL2Browser?VOfilter=biomed . Funding Information: This work was supported by European Union's Seventh Framework Programme ( FP7/2007-2013 ) under grant agreement n. 602102 (EPITARGET to A.V., A.F., W.L.) and by ARCEM association (M.R.). Publisher Copyright: © 2018

PY - 2019/4/1

Y1 - 2019/4/1

N2 - The lack of early biomarkers of epileptogenesis precludes a sound prediction of epilepsy development after acute brain injuries and of the natural course of the disease thus impairing the development of antiepileptogenic treatments. We investigated whether the dimensional changes of nonlinear dynamics in EEG/ECoG signals, that were recorded in the early aftermath of different epileptogenic injuries, provide a measure to be exploited as a sensitive prognostic and predictive biomarker for epilepsy. Using three different models of epilepsy in two rodent species, we report a common and significant decrease of nonlinear dynamics dimension in EEG/ECoG tracings during early epileptogenesis. In particular, the magnitude of this dimensional decrease predicts the severity of ensuing epilepsy, and this measure is modulated by disease-modifying or antiepileptogenic treatments. The broad application of EEG/ECoG monitoring in epilepsy underlines the translational value of these findings for enriching the population of patients at risk for developing epilepsy in clinical investigations.

AB - The lack of early biomarkers of epileptogenesis precludes a sound prediction of epilepsy development after acute brain injuries and of the natural course of the disease thus impairing the development of antiepileptogenic treatments. We investigated whether the dimensional changes of nonlinear dynamics in EEG/ECoG signals, that were recorded in the early aftermath of different epileptogenic injuries, provide a measure to be exploited as a sensitive prognostic and predictive biomarker for epilepsy. Using three different models of epilepsy in two rodent species, we report a common and significant decrease of nonlinear dynamics dimension in EEG/ECoG tracings during early epileptogenesis. In particular, the magnitude of this dimensional decrease predicts the severity of ensuing epilepsy, and this measure is modulated by disease-modifying or antiepileptogenic treatments. The broad application of EEG/ECoG monitoring in epilepsy underlines the translational value of these findings for enriching the population of patients at risk for developing epilepsy in clinical investigations.

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KW - Biomarker

KW - Disease modification treatments

KW - Recurrence quantification analysis

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DO - 10.1016/j.nbd.2018.12.014

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EP - 378

JO - Neurobiology of Disease

JF - Neurobiology of Disease

SN - 0969-9961

ER -

Changes of dimension of EEG/ECoG nonlinear dynamics predict epileptogenesis and therapy outcomes

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Keywords

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