Abstract
Objective. Electrical impedance tomography (EIT) is an imaging technique that produces tomographic images of internal impedance changes within an object using surface electrodes. It can be used to image the slow increase in cerebral tissue impedance that occurs over seconds during epileptic seizures, which is attributed to cell swelling due to disturbances in ion homeostasis following hypersynchronous neuronal firing and its associated metabolic demands. In this study, we characterised and imaged this slow impedance response during neocortical and hippocampal epileptiform events in the rat brain and evaluated its relationship to the underlying neural activity. Approach. Neocortical or hippocampal seizures, comprising repeatable series of high-amplitude ictal spikes, were induced by electrically stimulating the sensorimotor cortex or perforant path of rats anaesthetised with fentanyl-isoflurane. Transfer impedances were measured during ≥30 consecutive seizures, by applying a sinusoidal current through independent electrode pairs on an epicortical array, and combined to generate an EIT image of slow activity. Main results. The slow impedance responses were consistently time-matched to the end of seizures and EIT images of this activity were reconstructed reproducibly in all animals (p < 0.03125, N = 5). These displayed foci of activity that were spatially confined to the facial somatosensory cortex and dentate gyrus for neocortical and hippocampal seizures, respectively, and encompassed a larger volume as the seizure progressed. Centre-of-mass analysis of reconstructions revealed that this activity corresponded to the true location of the epileptogenic zone, as determined by EEG recordings and fast neural EIT measurements which were obtained simultaneously. Significance. These findings suggest that the slow impedance response presents a reliable marker of hypersynchronous neuronal activity during epileptic seizures and can thus be utilised for investigating the mechanisms of epileptogenesis in vivo and for aiding localisation of the epileptogenic zone during presurgical evaluation of patients with refractory epilepsies.
Highlights
30% of people with epilepsy are refractory to the available anticonvulsant medication and may benefit from surgical resection of epileptogenic tissue for seizure control (Nair, 2016)
A significance level of α = 0.01 was used for all statistical analyses. For both neocortical and hippocampal seizures, the mean centre of mass of reconstructed slow and fast neural activity was calculated across animals
As our results have shown that the reconstructed slow activity is correlated both to EEG and fast neural Electrical impedance tomography (EIT) recordings, they suggest that the slow impedance response is a reliable marker of neural activity during epileptic events and may be used for localising epileptogenic tissue in vivo and clinically
Summary
30% of people with epilepsy are refractory to the available anticonvulsant medication and may benefit from surgical resection of epileptogenic tissue for seizure control (Nair, 2016). 1962; Elazar, et al, 1966; Olsson, et al, 2006) This impedance increase is attributed to cell swelling which arises as a result of the high metabolic demands of intense neuronal activity during ictal events and causes the active cerebral tissue to outrun its available energy supplies, giving rise to anoxic depolarisation (Andrew & MacVicar, 1994; Dzhala, et al, 2000; Dreier, et al, 2011). By reducing the volume of extracellular fluid, cell swelling causes an increase in the measured cerebral tissue impedance
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