Functional expression of type 1 rat GABA transporter in microinjected Xenopus laevis oocytes.

In this chapter we describe technical aspects and experimental potential of the two electrodes voltage clamp (TEVC) electrophysiological approach applied to the Xenopus oocyte-expression system. This technique is addressed to the study of a particular class of expressed proteins, those responsible to drive ion fluxes through the plasma membrane. In fact the voltage-clamp technique provides the most direct and sensitive measurement of the functional properties of ion channels and electrogenic transporters, allowing specific ion currents to be recorded under well-defined voltage conditions and temporal control. Besides the study of the physiological properties of specific ion channels as well as their pharmacological modulation, further applications of the TEVC on oocytes include the possibility to introduce single point mutations in the channel construct and to infer to possible structural aspects and functional involvements of single amino acidic residues. To achieve these results these technique should be strictly tied to basic molecular biology techniques. Recent advance of this technique in drug discovery procedures have been briefly enlightened.

The anti-nociceptive agent ralfinamide inhibits tetrodotoxin-resistant and tetrodotoxin-sensitive Na+ currents in dorsal root ganglion neurons.

Tetrodotoxin-resistant and tetrodotoxin-sensitive Na+ channels contribute to the abnormal spontaneous firing in dorsal root ganglion neurons associated with neuropathic pain. Effects of the anti-nociceptive agent ralfinamide on tetrodotoxin-resistant and tetrodotoxin-sensitive currents in rat dorsal root ganglion neurons were therefore investigated by patch clamp experiments. Ralfinamide inhibition was voltage-dependent showing highest potency towards inactivated channels. IC50 values for tonic block of half-maximal inactivated tetrodotoxin-resistant and tetrodotoxin-sensitive currents were 10 microM and 22 microM. Carbamazepine, an anticonvulsant used in the treatment of pain, showed significantly lower potency. Ralfinamide produced a hyperpolarising shift in the steady-state inactivation curves of both currents confirming the preferential interaction with inactivated channels. Additionally, ralfinamide use and frequency dependently inhibited both currents and significantly delayed repriming from inactivation. All effects were more pronounced for tetrodotoxin-resistant than tetrodotoxin-sensitive currents. The potency and mechanisms of actions of ralfinamide provide a hypothesis for the anti-nociceptive properties found in animal models.

Ion channel blockers for the treatment of neuropathic pain.

Neuropathic pain, a severe chronic pain condition characterized by a complex pathophysiology, is a largely unmet medical need. Ion channels, which underlie cell excitability, are heavily implicated in the biological mechanisms that generate and sustain neuropathic pain. This review highlights the biological evidence supporting the involvement of voltage-, proton- and ligand-gated ion channels in the neuropathic pain setting. Ion channel modulators at different research or development stages are reviewed and referenced. Ion channel modulation is one of the main avenues to achieve novel, improved neuropathic pain treatments. Voltage-gated sodium and calcium channel and glutamate receptor modulators are likely to produce new, improved agents in the future. Rationally targeting subtypes of known ion channels, tackling recently discovered ion channel targets or combining drugs with different mechanism of action will be primary sources of new drugs in the longer term.

Ralfinamide administered orally before hindpaw neurectomy or postoperatively provided long-lasting suppression of spontaneous neuropathic pain-related behavior in the rat.

Ralfinamide is analgesic when applied as a single dose in rodent models of stimulus-evoked chronic pain. However, it is unknown whether its chronic application after nerve injury can suppress spontaneous chronic pain, the main symptom driving patients to seek treatment. In this study ralfinamide was administered to rats at doses producing plasma levels similar to those causing analgesia in pain patients. The analgesic effect was tested on autotomy, a behavior of self-mutilation of a denervated paw that models spontaneous neuropathic pain. Sprague-Dawley male rats (N=10-20/group) underwent transection of the sciatic and saphenous nerves unilaterally. Ralfinamide or its vehicle were administered per os for 7 days preoperatively (80 mg/kg; bid), followed by the vehicle or Ralfinamide, until postoperative d42. Autotomy was scored daily until d63. Lasting 'preemptive analgesia' was found in rats treated with ralfinamide preoperatively, expressed by delayed autotomy onset (P=0.009) and reduced scores on d63 (P=0.01). Rats treated with ralfinamide (30 or 60 mg/kg; bid) from the operation till d42, but not preoperatively, also showed delayed autotomy (P=0.05, P=0.006), and reduced autotomy scores lasting till d63 (P=0.02, P=0.01), for the two doses, respectively. Combining ralfinamide treatments for 7 days preoperatively and 42 days postoperatively also resulted in significantly suppressed scores on d42 and d63 (P=0.005, P=0.001, respectively). Suppression of neuropathic pain-related behavior was likely caused by a combination of mechanisms reported for ralfinamide, including inhibition of Na+ and Ca++ currents in Nav1.3, Nav1.7, Nav1.8, and Cav2.2 channels in rat DRG neurons, inhibition of substance P release from spinal cord synaptosomes, NMDA receptor antagonism and neuroprotection.

The therapeutic potential of Na+ and Ca2+ channel blockers in pain management.

Chronic pain affects a large percentage of the population, representing a socio-economic burden. Current treatments are characterised by suboptimal efficacy and/or side effects that limit their use. Among several approaches to treating chronic pain, voltage-sensitive Ca(2+) and Na(+) channels are promising targets. This review evaluates the preclinical evidence that supports the involvement of these targets, with specific attention to those subtypes that appear more strictly correlated with pain generation and sustainment, as well as those compounds that modulate the activity of Ca(2+) and/or Na(+) channels that are currently in clinical development for chronic pain conditions.