A seizure is the manifestation of the abnormal synchronous activation of a group of neurons. This is thought to be caused by an imbalance between neuronal excitation and inhibition. Recruitment of neurons during seizure can occur not only by excitatory glutamate-dependent synaptic transmission but also by extra-synaptic ephaptic coupling, a process during which local extracellular electrical fields generated by adjacent neurons feedback onto the electrical potential across the neuronal membrane. Inhibitory gamma-hydroxy-butyric acid (GABA)-dependent synaptic transmission represses seizure initiation and propagation (Fig. 18.2). Both synaptic and extra-synaptic transmission can be disrupted by changes in the electrolyte and acid-base composition of the extracellular fluid.

Extracellular low osmolality and hyponatremia increase neuronal excitability through various mechanisms [7–10]. To some extent, they enhance excitatory neurotransmission at the pre- and post-synaptic levels by facilitating calcium uptake [11, 12]. But the most important effect of low osmolality, whether it is caused or not by hyponatremia, occurs through cellular swelling, which enhances ephaptic coupling [7, 10, 13]. Additional effects of astrocytic swelling include the disruption of glutamate-glutamine metabolism and the release of excitatory amino acids by astrocytes [14, 15]. Low extracellular chloride concentrations also contribute to increase excitability by depressing GABA-dependent inhibitory currents [16]. Hyperosmolality has the reverse effect and decreases neuronal excitability [17].

Calcium and magnesium ions both are voltage membrane stabilizers. They screen surface negative charges on neuronal membranes and regulate the activation of voltage-gated ion channels [9, 18]. There is an inverse correlation between extracellular calcium concentrations and neuronal excitability [19]. Immersing hippocampal slices in a low-calcium solution provokes the occurrence of spontaneous synchronized bursts similar to epileptiform discharges [20]. This is at least in part explained by an increase in resting membrane potential and a decrease of the firing threshold [21] and occurs even when excitatory neurotransmission is blocked [22]. Conversely, a high-calcium solution completely prevents seizure-like activity in hippocampal slices [23]. Similar findings are observed when manipulating extracellular magnesium concentrations in vitro. Sporadic epileptiform bursts followed by ictal discharges develop when hippocampal slices are bathed in a low-magnesium solution [23–26]. Calcium and magnesium ions act as antagonists at all chemical synapses. Calcium ions enter the pre-synaptic axon terminals through voltage-gated channels and bind to protein complexes, allowing the fusion of vesicles to the synaptic membrane and the release of neurotransmitters into the synaptic cleft (Fig. 18.2) [27–29]. Calcium entry through ligand-gated channels at the post-synaptic levels, such as the glutamate N-methyl-d-aspartate (NMDA) receptors, also contributes to excitatory neurotransmission. On the other hand, magnesium ions limit the influx of calcium ions through pre-synaptic voltage-dependent channels and thus modulate neurotransmitter release [25]. In addition, they also regulate synaptic transmission at the post-synaptic level by gating glutamate NMDA receptors in a voltage-dependent manner. At normal resting membrane potential, magnesium ions occupy a site inside the channel part of the receptor and prevent the influx of sodium and calcium ions. If synaptic excitation through other types of glutamate receptors (alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid [AMPA] and kainate) causes sufficient depolarization, magnesium ions translocate out of the channels, which open [26, 30, 31].

While both synaptic potentiation and membrane destabilization are necessary to generate epileptiform discharges and seizures in the low-magnesium model of seizures [23], synaptic transmission is not necessary and in fact abolished in the low-calcium condition [32]. Neuronal synchronization thus has to occur in an ephaptic manner or through gap junctions.

The effect of pH and protons on neuronal excitability has received relatively little attention compared to other ions [33]. Current evidence indicates that the binding of protons to membrane proteins affects their conformation and their functional properties. Proteins whose activity is modulated by pH include voltage-gated ion channels, GABA receptors, NMDA receptors, gap junctions, calcium-sensing, and pH cation channels [16–24]. Acidosis has little influence on resting membrane potential [34] or axonal conduction [35] but decreases synaptic transmission by both pre- and post-synaptic mechanisms [34–36] and can suppress seizures [37, 38].