tetrodotoxin and Stroke

Most processing of sensation involves the cortical hemisphere opposite (contralateral) to the stimulated limb. Stroke patients can exhibit changes in the interhemispheric balance of sensory signal processing. It is unclear whether these changes are the result of poststroke rewiring and experience, or whether they could result from the immediate effect of circuit loss. We evaluated the effect of mini-strokes over short timescales (<2 h) where cortical rewiring is unlikely by monitoring sensory-evoked activity throughout much of both cortical hemispheres using voltage-sensitive dye imaging. Blockade of a single pial arteriole within the C57BL6J mouse forelimb somatosensory cortex reduced the response evoked by stimulation of the limb contralateral to the stroke. However, after stroke, the ipsilateral (uncrossed) forelimb response within the unaffected hemisphere was spared and became independent of the contralateral forelimb cortex. Within the unaffected hemisphere, mini-strokes in the opposite hemisphere significantly enhanced sensory responses produced by stimulation of either contralateral or ipsilateral pathways within 30-50 min of stroke onset. Stroke-induced enhancement of responses within the spared hemisphere was not reproduced by inhibition of either cortex or thalamus using pharmacological agents in nonischemic animals. I/LnJ acallosal mice showed similar rapid interhemispheric redistribution of sensory processing after stroke, suggesting that subcortical connections and not transcallosal projections were mediating the novel activation patterns. Thalamic inactivation before stroke prevented the bilateral rearrangement of sensory responses. These findings suggest that acute stroke, and not merely loss of activity, activates unique pathways that can rapidly redistribute function within the spared cortical hemisphere.

Topics: Animals; Disease Models, Animal; Forelimb; Male; Mice; Mice, Inbred C57BL; Models, Biological; Neuronal Plasticity; Pia Mater; Somatosensory Cortex; Stroke; Tetrodotoxin; Thalamus; Voltage-Sensitive Dye Imaging

Sipatrigine (BW619C89), a derivative of the antiepileptic agent lamotrigine, has potent neuroprotective properties in animal models of cerebral ischemia and head injury. In the present study we investigated the electrophysiological effects of sipatrigine utilizing intracellular current-clamp recordings obtained from striatal spiny neurons in rat corticostriatal slices and whole-cell patch-clamp recordings in isolated striatal neurons. The number of action potentials produced in response to a depolarizing current pulse in the recorded neurons was reduced by sipatrigine (EC(50) 4.5 microM). Although this drug preferentially blocked action potentials in the last part of the depolarizing current pulse, it also decreased the frequency of the first action potentials. Sipatrigine also inhibited tetrodotoxin-sensitive sodium (Na(+)) current recorded from isolated striatal neurons. The EC(50) for this inhibitory action was 7 microM at the holding potential (V(h)) of -65 mV, but 16 microM at V(h) = -105, suggesting a dependence of this pharmacological effect on the membrane potential. Moreover, although the inhibitory action of sipatrigine on Na(+) currents was maximal during high-frequency activation (20 Hz), it could also be detected at low frequencies. The amplitude of excitatory postsynaptic potentials (EPSPs), recorded following stimulation of the corticostriatal pathway, was depressed by sipatrigine (EC(50) 2 microM). This inhibitory action, however, was incomplete; in fact maximal concentrations of this drug reduced EPSP amplitude by only 45%. Sipatrigine produced no increase in paired-pulse facilitation, suggesting that the modulation of a postsynaptic site was the main pharmacological effect of this agent. The inhibition of voltage-dependent Na(+) channels exerted by sipatrigine might account for its depressant effects on both repetitive firing discharge and corticostriatal excitatory transmission. The modulation of Na(+) channels described here, as well as the previously observed inhibition of high-voltage-activated calcium currents, might contribute to the neuroprotective efficacy exerted by this compound in experimental models of in vitro and in vivo ischemia.

Topics: Action Potentials; Animals; Anticonvulsants; Brain Chemistry; Calcium Channels; Corpus Striatum; Epilepsy; Excitatory Postsynaptic Potentials; In Vitro Techniques; Lamotrigine; Male; Neurons; Neuroprotective Agents; Patch-Clamp Techniques; Piperazines; Pyrimidines; Rats; Rats, Wistar; Sodium; Stroke; Tetrodotoxin; Triazines