The effects of amphetamine preexposure on electrical kindling of the hippocampus and related transfer phenomena

Contralesional hippocampal spreading depolarization promotes functional recovery after stroke

Ischemic stroke, brain tissue infarction following obstructed cerebral blood flow, leads to long-term neurological deficits and death. While neocortex is a commonly affected region with established preclinical models, less is known about deeper brain strokes, despite having unique neurological outcomes. We induced focal ischemic stroke while simultaneously monitoring neuronal activity in awake behaving Thy1-GCaMP6f mice by delivering and collecting light through bilateral fiberoptic implants. Unilateral hippocampal stroke resulted in atypical wandering behavior coincident with ipsilesional terminal spreading depolarization (sustained increase in GCaMP6f fluorescence). Ischemia induced seizures that propagated to the contralesional hippocampus triggering a transient spreading depolarization, predominantly in females. Hippocampal stroke impaired contextual fear conditioning acquired pre-stroke. Yet, 7 days post-stroke, contextual fear conditioning was only improved in mice with contralesional spreading depolarization. Blunting peri-stroke contralesional spreading depolarization prevented recovery of hippocampus-dependent learning. Together, we show that regionally isolated deleterious and beneficial spreading depolarizations can occur concurrently in the murine brain during acute stroke.

Secondary Epileptogenesis: Common to See, but Possible to Treat?

Secondary epileptogenesis is a common phenomenon in epilepsy, characterized by epileptiform discharges from the regions outside the primary focus. It is one of the major reasons for pharmacoresistance and surgical failure. Compared with primary epileptogenesis, the mechanism of secondary epileptogenesis is usually more complex and diverse. In this review, we aim to summarize the characteristics of secondary epileptogenesis from both clinical and laboratory studies in a historical view. Mechanisms of secondary epileptogenesis in molecular, cellular, and circuity levels are further presented. Potential treatments targeting the process are discussed as well. At last, we highlight the importance of circuitry studies, which would further illustrate precise treatments of secondary epileptogenesis in the future.

Amphetamine and antidepressant drug effects on GABA- and NMDA-related seizures

Research has shown a synergistic relationship between amphetamine sensitization and limbic system kindling. To explore the role of GABA and NMDA receptor activity in modulating the positive effects of amphetamine on epileptogenesis, alterations in GABA- and NMDA-related convulsions were examined after acute and chronic amphetamine administration. A single injection of d-amphetamine (7.5 mg/kg) significantly decreased latencies to generalized motor seizures induced 12 h later by the noncompetitive GABAA receptor antagonist picrotoxin (10 mg/kg). The increased sensitivity to clonus was specific to acute amphetamine treatment and was not evident following withdrawal from chronic drug exposure. Seizures induced by NMDLA (1,000 mg/kg), on the other hand, were not modified by acute amphetamine injection; however, the latency to clonus was reduced substantially after NMDLA injection to mice chronically preexposed to amphetamine. The short- and long-term amphetamine effects on GABA- and NMDA-associated convulsive activity were not paralleled by similar drug treatment schedules involving acute (20 mg/kg) and chronic administration of desipramine, zimelidine, and buproprion. These results suggest that amphetamine may be acting on inhibitory and excitatory amino acid systems independently of its monoaminergic properties. The implications of these findings were discussed in relation to amphetamine sensitization of mesolimbic functioning.

Sensitization of mesolimbic brain stimulation reward after electrical kindling of the amygdala

The effects of partial kindling of the central amygdaloid nucleus on brain stimulation reward were evaluated. Intracranial self-stimulation (ICSS) rate intensity functions were determined using a two-hole nose-poke discrimination paradigm in rats implanted with electrodes in the A10 dopamine (DA) neuronal region of the ventral tegmental area (VTA), and in the medial forebrain bundle (MFB) at the level of the lateral hypothalamus. The kindling process did not influence ICSS baseline rates from either site. However, following stage 4 kindling, a low dose amphetamine challenge increased ICSS, resulted in a significant shift to the left of the rate intensity functions, and decreased reward thresholds. Analysis of the error scores which consisted of nonreinforced responses made during ICSS testing revealed that the interaction between kindling and amphetamine on ICSS was specific to changes in central reward processes, and could not be attributed to the influence of rate-enhancing performance variables. The kindling-elicited sensitization of mesolimbic DA reward functioning seen after amphetamine challenge was discussed in relation to the role of the central amygdala in the integration of stimulus-reward associations, and in the conditioning of affective emotional states.