Spike densities of the amygdala and neocortex reflect progression of kindled motor seizures

Amygdala kindling is a common temporal lobe-like seizure model. In the present study, temporal and spectral analyses of the ictal period were investigated throughout amygdala kindling in response to different behavioral seizures. Right-side amygdala was kindled to induce epileptiform afterdischarges...

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Bibliographic Details
Published in:Medical & biological engineering & computing 2018, Vol.56 (1), p.99-112
Main Authors: Wang, Yu-Lin, Liang, Sheng-Fu, Su, Alvin W. Y., Shaw, Fu-Zen
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Amygdala
Amygdala - physiopathology
Animal memory
Animals
Behavior, Animal
Biomedical and Life Sciences
Biomedical Engineering and Bioengineering
Biomedicine
Computer Applications
Convulsions & seizures
Cortex (frontal)
Density
Epilepsy
Frequencies
Human Physiology
Imaging
Kindling
Kindling, Neurologic - physiology
Male
Neocortex - physiopathology
Original Article
Radiology
Rats, Wistar
Seizing
Seizures
Seizures - physiopathology
Spectra
Spectral methods
Temporal lobe
Time Factors
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Summary:Amygdala kindling is a common temporal lobe-like seizure model. In the present study, temporal and spectral analyses of the ictal period were investigated throughout amygdala kindling in response to different behavioral seizures. Right-side amygdala was kindled to induce epileptiform afterdischarges (ADs). ADs of both the frontal cortex and amygdala were analyzed. Powers of the low (0–9 Hz)- and high (12–30 Hz)-frequency bands in response to different behavioral seizures were calculated. Densities of upward and downward peaks of spikes, which reflected information of spike count and spike pattern, throughout kindle-induced ADs were calculated. Progression was seen in the temporal and spectral characteristics of amygdala-kindled ADs in response to behaviors. Numbers of significant differences of all 1-s AD segments between two Racine’s seizure stages were significantly higher in upward and downward indexes of the temporal spike than those using the spectral method in both the amygdala and neocortex. Ability for distinguishing seizure stages was significantly higher in temporal spike density of amygdala ADs compared to those of frontal ADs. Our results showed that amygdala kindling caused spectrotemporal changes of activities in the amygdala and frontal cortex. The density of spike-related peaks had better distinguishability in response to behavioral seizures, particularly in a seizure zone of amygdala. The present study provides a new temporal index of spike’s peak density to understand progression of motor seizures in the kindling process.
ISSN:0140-0118
1741-0444
DOI:10.1007/s11517-017-1672-4