The single-evoked epileptic afterdi

The single-evoked epileptic afterdischarges model (AD) is
another important approach to electrical stimulation. It is
induced in specifc brain regions, resembling complex partial
seizures if applied into limbic structures and myoclonic seizures if applied into the sensorimotor cortex. AD is useful for
investigating electrophysiological and behavioral correlates
of focally generated seizure-like patterns that often spread to
nonstimulated networks.Electrographic properties of AD
largely depend on the brain region stimulated. For instance,
spike-and-wave patterns can be elicited by AD induction
either in the neocortex or mediodorsal thalamus. In contrast,
AD induction in limbic circuits produces fast spikes, large
delta waves, and/or sharp theta waves. The most common
target for electrically induced AD is the hippocampus.
Once hippocampal AD ends, postictal refractoriness, which
precludes subsequent seizures, is often observed.This
period is followed by a pattern of low-amplitude and fast
oscillations (40–80 Hz), also defned as the AD termination
oscillation. Behavioral alterations induced by hippocampal
AD include freezing during stimulus, wet dog shake at the
end or just after the stimulus, and hyperlocomotion and
stereotypies (eg, excessive grooming, rearing, and/or head
movements), along with the AD termination oscillations.
Some authors claim that AD experiments can probe underlying mechanisms of the relationship between psychosis and
epilepsy (eg, postictal psychosis).59,60 In fact, it has been
reported that hippocampal AD induction enhances gamma
oscillations in the nucleus accumbens and medial prefrontal
cortex and that such an effect is associated with hyperlocomotion and stereotypies. These alterations can be reversed
by treatment with the typical antipsychotic haloperidol.
As a consequence, hippocampal AD produces sensorimotor gating defcits, measured by prepulse inhibition of the
acoustic startle 2 minutes after electrical stimulation. To
date, Osawa et al were the frst group to report the beneft of
using optogenetics to probe hippocampal AD. The authors
were able to overcome some technical limitations of the
electrical stimulation; namely, the inability to manipulate
the activity of specifc groups of neurons and the unfeasibility of studying the spatial–temporal dynamics of neuronal
activity during stimulation because of contamination of the
electrophysiological recordings by electrical artifacts.In
addition to developing an electrical artifact-free model of AD,
the authors provide further understanding of the generation
and termination of seizure-like activity in the septo-temporal
axis of the hippocampus.