Epileptiform activity induced by changes in extracellular potassium in hippocampus

Rutecki, Paul; Lebeda, Frank J.; Johnston, Daniel

doi:10.1152/jn.1985.54.5.1363

Cited by 229 publications

(143 citation statements)

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“…Many of them rely on blocking GABA A receptor mediated inhibition with drugs such as picrotoxin, bicuculline or penicillin (Dingledine and Gjerstad, 1979;Schwartzkroin and Prince, 1978). Convulsant treatments which do not block inhibition include 4-aminopyridine (Avoli et al, 1996;D'Antuono et al, 2002;Rutecki et al, 1987), elevated K + (Jiruska et al, 2010a;Rutecki et al, 1985;Traub and Dingledine, 1990) and low Mg 2+ (Anderson et al, 1986;Derchansky et al, 2008). Another acute and realistic model in vivo is brain trauma, which leads to electrographic seizures in the majority of animals (Topolnik et al, 2003).…”

Section: Acute Models Of Epilepsy-convulsant Drugsand Changes In Extrmentioning

confidence: 99%

Mechanisms of physiological and epileptic HFO generation

Jefferys

Prida

Wendling

et al. 2012

Progress in Neurobiology

261

232

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High frequency oscillations (HFO) have a variety of characteristics: band-limited or broad-band, transient burst-like phenomenon or steady-state. HFOs may be encountered under physiological or under pathological conditions (pHFO). Here we review the underlying mechanisms of oscillations, at the level of cells and networks, investigated in a variety of experimental in vitro and in vivo models. Diverse mechanisms are described, from intrinsic membrane oscillations to network processes involving different types of synaptic interactions, gap junctions and ephaptic coupling. HFOs with similar frequency ranges can differ considerably in their physiological mechanisms. The fact that in most cases the combination of intrinsic neuronal membrane oscillations and synaptic circuits are necessary to sustain network oscillations is emphasized. Evidence for pathological HFOs, particularly fast ripples, in experimental models of epilepsy and in human epileptic patients is scrutinized. The underlying mechanisms of fast ripples are examined both in the light of animal observations, in vivo and in vitro, and in epileptic patients, with emphasis on single cell dynamics. Experimental observations and computational modeling have led to hypotheses for these mechanisms, several of which are considered here, namely the role of out-ofphase firing in neuronal clusters, the importance of strong excitatory AMPA-synaptic currents and recurrent inhibitory connectivity in combination with the fast time scales of IPSPs, ephaptic coupling and the contribution of interneuronal coupling through gap junctions. The statistical behaviour of fast ripple events can provide useful information on the underlying mechanism and can help to further improve classification of the diverse forms of HFOs.

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Section: Acute Models Of Epilepsy-convulsant Drugsand Changes In Extrmentioning

confidence: 99%

Mechanisms of physiological and epileptic HFO generation

Jefferys

Prida

Wendling

et al. 2012

Progress in Neurobiology

261

232

View full text Add to dashboard Cite

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“…However, the pioneering studies made in Johnston's laboratory with single-electrode voltage-clamp recordings have demonstrated that the amplitude of the interictal responses recorded during application of medium containing 4AP, tetraethylammonium, or elevated [K + ] are characterized by reversal potentials that are more negative than those associated with reversal potentials of paroxysmal depolarization shifts induced by GABA A receptor antagonists (Rutecki et al, 1985(Rutecki et al, , 1987(Rutecki et al, , 1990. Hence, synaptic inhibition is operative in these in vitro models of interictal discharge.…”

Section: Fast Ca3-driven Interictal Activitymentioning

confidence: 99%

GABAergic synchronization in the limbic system and its role in the generation of epileptiform activity

Avoli¹,

Curtis²

2011

Progress in Neurobiology

221

246

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GABA is the main inhibitory neurotransmitter in the adult forebrain, where it activates ionotropic type A and metabotropic type B receptors. Early studies have shown that GABA A receptormediated inhibition controls neuronal excitability and thus the occurrence of seizures. However, more complex, and at times unexpected, mechanisms of GABAergic signaling have been identified during epileptiform discharges over the last few years. Here, we will review experimental data that point at the paradoxical role played by GABA A receptor-mediated mechanisms in synchronizing neuronal networks, and in particular those of limbic structures such as the hippocampus, the entorhinal and perirhinal cortices, or the amygdala. After having summarized the fundamental characteristics of GABA A receptor-mediated mechanisms, we will analyze their role in the generation of network oscillations and their contribution to epileptiform synchronization. Whether and how GABA A receptors influence the interaction between limbic networks leading to ictogenesis will be also reviewed. Finally, we will consider the role of altered inhibition in the human epileptic brain along with the ability of GABA A receptor-mediated conductances to generate synchronous depolarizing events that may lead to ictogenesis in human epileptic disorders as well.

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“…2 A) (see Figs. 3-7) (Rutecki et al, 1985). This [K ϩ ] o diminishes neuronal Cl Ϫ extrusion by decreasing the driving force for K-Cl cotransport, thereby making the GABA reversal potential more positive (Thompson and Gahwiler, 1989b).…”

Section: Contributions Of Synaptic Activities To Firing Rates Of Hippmentioning

confidence: 99%

Excitatory Actions of Endogenously Released GABA Contribute to Initiation of Ictal Epileptiform Activity in the Developing Hippocampus

2003

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In the developing rat hippocampus, ictal epileptiform activity can be elicited easily in vitro during the first three postnatal weeks. Changes in neuronal ion transport during this time cause the effects of GABA A receptor (GABA A -R) activation to shift gradually from strongly depolarizing to hyperpolarizing. It is not known whether the depolarizing effects of GABA and the propensity for ictal activity are causally linked. A key question is whether the GABA-mediated depolarization is excitatory, which we defined operationally as being sufficient to trigger action potentials. We assessed the effect of endogenous GABA on ictal activity and neuronal firing rate in hippocampal slices from postnatal day 1 (P1) to P30. In extracellular recordings, there was a strong correlation between the postnatal age at which GABA A -R antagonists decreased action potential frequency (P23) and the age at which ictal activity could be induced by elevated potassium (P23). In addition, there was a strong correlation between the fraction of slices in which ictal activity was induced by elevated potassium concentrations and the fractional decrease in action potential firing when GABA A -Rs were blocked in the presence of ionotropic glutamate receptor antagonists. Finally, ictal activity induced by elevated potassium was blocked by the GABA A -R antagonists bicuculline and SR-95531 (gabazine) and increased in frequency and duration by GABA A -R agonists isoguvacine and muscimol. Thus, the propensity of the developing hippocampus for ictal activity is highly correlated with the effect of GABA on action potential probability and reversed by GABA A antagonists, indicating that GABA-mediated excitation is causally linked to ictal activity in this developmental window.

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Epileptiform activity induced by changes in extracellular potassium in hippocampus

Cited by 229 publications

References 0 publications

Mechanisms of physiological and epileptic HFO generation

Mechanisms of physiological and epileptic HFO generation

GABAergic synchronization in the limbic system and its role in the generation of epileptiform activity

Excitatory Actions of Endogenously Released GABA Contribute to Initiation of Ictal Epileptiform Activity in the Developing Hippocampus

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