A hyperthermic seizure unleashes a surge of spreading depolarizations in Scn1a-deficient mice
Isamu Aiba, … , Yao Ning, Jeffrey L. Noebels
Isamu Aiba, … , Yao Ning, Jeffrey L. Noebels
Published August 8, 2023
Citation Information: JCI Insight. 2023;8(15):e170399. https://doi.org/10.1172/jci.insight.170399.
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Research Article Neuroscience

A hyperthermic seizure unleashes a surge of spreading depolarizations in Scn1a-deficient mice

Abstract

Spreading depolarization (SD) is a massive wave of cellular depolarization that slowly migrates across the brain gray matter. Cortical SD is frequently generated following brain injury, while less is understood about its potential contribution to genetic disorders of hyperexcitability, such as SCN1A-deficient epilepsy, in which febrile seizure often contributes to disease initiation. Here we report that spontaneous SD waves are predominant EEG abnormalities in the Scn1a-deficient mouse (Scn1a+/R1407X) and undergo sustained intensification following a single hyperthermic seizure. Chronic DC-band EEG recording detected spontaneous SDs, seizures, and seizure-SD complexes in Scn1a+/R1407X mice but not WT littermates. The SD events were infrequent, while a single hyperthermia-induced seizure robustly increased SD frequency over 4-fold during the initial postictal week. This prolonged neurological aftermath could be suppressed by memantine administration. Video, electromyogram, and EEG spectral analysis revealed distinct neurobehavioral patterns; individual seizures were associated with increased motor activities, while SDs were generally associated with immobility. We also identified a stereotypic SD prodrome, detectable over a minute before the onset of the DC potential shift, characterized by increased motor activity and bilateral EEG frequency changes. Our study suggests that cortical SD is a pathological manifestation in SCN1A-deficient epileptic encephalopathy.

Authors

Isamu Aiba, Yao Ning, Jeffrey L. Noebels

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Figure 3

Electrophysiological characteristics of PGES and postictal SD.

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Electrophysiological characteristics of PGES and postictal SD. (A) Repre...
(A) Representative trace showing the temporal sequence of PGES (depressed EEG amplitude, blue window) and postictal SD generation. Top: DC; middle: high pass (>1 Hz); bottom: EEG converted into power. (B and C) The PGES incidence (B) and duration (C) were similar in seizure without postictal SD and seizure with postictal SD. Seizure only: n = 55; seizure+SD: n = 20. (D) The latency to SD after seizure termination is significantly prolonged after a hyperthermic seizure. Baseline: n = 11; after hyperthermic seizure: n = 32. (EH) Comparison of seizure/SD kinetics between those in isolated events and those in the seizure+SD complex. The duration of SD in the seizure+SD complex is shorter than the duration of SD detected alone (E), while the DC amplitudes were not different (F). Similarly, the duration of seizure in the seizure+SD complex is shorter than the duration of seizure that appeared without SD (G), while the DC amplitudes were not different (H). SD only: n = 160; seizure only: n = 95; seizure+SD: n = 43. Statistics were computed by Mann-Whitney U test.