Altered inhibition in the hippocampal neural networks after spreading depression.

Prolonged neuronal depression after spreading depression (SD) is followed by a late cellular and synaptic hyperexcitability. Intra- and extracellular recordings of bioelectrical activities were performed in the rodent hippocampus to investigate the role of γ-aminobutyric acid (GABA)-mediated inhibition in the late hyperexcitable state of SD. The effect of KCl-induced negative DC potential shifts was investigated on extracellularly recorded paired-pulse depression (PPD) and bicuculline-induced afterdischarges as well as intracellularly recorded inhibitory post synaptic potentials (IPSPs) in the hippocampal CA1 area. The results revealed that SD decreased the degree of PPD, enhanced the number and duration of bicuculline-induced afterdischarges, and reduced the amplitude and duration of IPSPs. Application of low concentrations of bicuculline before the induction of SD enhanced the inhibitory effect of SD on IPSPs. Data indicate the contribution of GABA-mediated inhibition to SD-induced delayed hyperexcitability. Modulation of GABA function in the late hyperexcitability phase of SD may play a role in therapeutic management of SD-related neurological disorders.

Cortical spreading depression modulates the caudate nucleus activity.

Cortical spreading depression (CSD) plays an important role in migraine with aura. The caudate nucleus has crucial functional interactions with brain regions likely to be important in migraine. The aim of the present in vitro study was to investigate the effect of CSD on the neuronal activity of the caudate. Intracellular recording was performed in the head of the caudate nucleus alongside of extracellular recording in Wistar rat somatosensory cortex. CSD was induced by local KCl injection. Changes in the membrane potentials of the caudate neurons began 1.2±0.2min after CSD. The neurons of the caudate nucleus depolarized first gradually and slightly then it depolarized abruptly at nearly the same point of time of the recovery of the cortical DC potential. Action potentials (APs) reappeared after the cortical DC shift returned to the baseline. Forty-five minutes after CSD, the caudate neurons showed lower frequency of APs and larger amplitude of depolarization prior to APs. The firing pattern of the caudate neurons evoked by injection of intracellular current pulses changed from slow adapting to fast adapting after CSD. Reduced neuronal activity in the caudate after CSD may be assumed to contribute to pain as well as changes in cognition and behavior in patients with migraine.