TY - JOUR
T1 - Electrocorticographic dynamics as a novel biomarker in five models of epileptogenesis
AU - Milikovsky, Dan Z.
AU - Weissberg, Itai
AU - Kamintsky, Lyn
AU - Lippmann, Kristina
AU - Schefenbauer, Osnat
AU - Frigerio, Federica
AU - Rizzi, Massimo
AU - Sheintuch, Liron
AU - Zelig, Daniel
AU - Ofer, Jonathan
AU - Vezzani, Annamaria
AU - Friedman, Alon
N1 - Publisher Copyright:
© 2017 the authors.
PY - 2017/4/26
Y1 - 2017/4/26
N2 - Postinjury epilepsy (PIE) is a devastating sequela of various brain insults. While recent studies offer novel insights into the mechanisms underlying epileptogenesis and discover potential preventive treatments, the lack of PIE biomarkers hinders the clinical implementation of such treatments. Here we explored the biomarker potential of different electrographic features in five models of PIE. Electrocorticographic or intrahippocampal recordings of epileptogenesis (from the insult to the first spontaneous seizure) from two laboratories were analyzed in three mouse and two rat PIE models. Time, frequency, and fractal and nonlinear properties of the signals were examined, in addition to the daily rate of epileptiform spikes, the relative power of five frequency bands (theta, alpha, beta, low gamma, and high gamma) and the dynamics of these features over time. During the latent pre-seizure period, epileptiform spikes were more frequent in epileptic compared with nonepileptic rodents; however, this feature showed limited predictive power due to high inter- and intra-animal variability. While nondynamic rhythmic representation failed to predict epilepsy, the dynamics of the theta band were found to predict PIE with a sensitivity and specificity of >90%. Moreover, theta dynamics were found to be inversely correlated with the latency period (and thus predict the onset of seizures) and with the power change of the high-gamma rhythm. In addition, changes in theta band power during epileptogenesis were associated with altered locomotor activity and distorted circadian rhythm. These results suggest that changes in theta band during the epileptogenic period may serve as a diagnostic biomarker for epileptogenesis, able to predict the future onset of spontaneous seizures.
AB - Postinjury epilepsy (PIE) is a devastating sequela of various brain insults. While recent studies offer novel insights into the mechanisms underlying epileptogenesis and discover potential preventive treatments, the lack of PIE biomarkers hinders the clinical implementation of such treatments. Here we explored the biomarker potential of different electrographic features in five models of PIE. Electrocorticographic or intrahippocampal recordings of epileptogenesis (from the insult to the first spontaneous seizure) from two laboratories were analyzed in three mouse and two rat PIE models. Time, frequency, and fractal and nonlinear properties of the signals were examined, in addition to the daily rate of epileptiform spikes, the relative power of five frequency bands (theta, alpha, beta, low gamma, and high gamma) and the dynamics of these features over time. During the latent pre-seizure period, epileptiform spikes were more frequent in epileptic compared with nonepileptic rodents; however, this feature showed limited predictive power due to high inter- and intra-animal variability. While nondynamic rhythmic representation failed to predict epilepsy, the dynamics of the theta band were found to predict PIE with a sensitivity and specificity of >90%. Moreover, theta dynamics were found to be inversely correlated with the latency period (and thus predict the onset of seizures) and with the power change of the high-gamma rhythm. In addition, changes in theta band power during epileptogenesis were associated with altered locomotor activity and distorted circadian rhythm. These results suggest that changes in theta band during the epileptogenic period may serve as a diagnostic biomarker for epileptogenesis, able to predict the future onset of spontaneous seizures.
KW - Biomarker
KW - EEG
KW - Epilepsy
KW - Epileptogenesis
KW - Stroke
KW - Traumatic brain injury
UR - http://www.scopus.com/inward/record.url?scp=85019140429&partnerID=8YFLogxK
U2 - 10.1523/JNEUROSCI.2446-16.2017
DO - 10.1523/JNEUROSCI.2446-16.2017
M3 - Article
C2 - 28330876
AN - SCOPUS:85019140429
SN - 0270-6474
VL - 37
SP - 4450
EP - 4461
JO - Journal of Neuroscience
JF - Journal of Neuroscience
IS - 17
ER -