Dissociable effects of lidocaine inactivation of the rostral and caudal basolateral amygdala on the maintenance and reinstatement of cocaine-seeking behavior in rats.

Cocaine addiction is a chronically relapsing brain disease, but its neural basis is not yet well understood. Clinical reports underscore the possible importance of associative processes for regulating at least some aspects of cocaine addiction. The present study reports the effects of reversible lidocaine-induced inactivation of rostral basolateral amygdala (rBLA) and caudal basolateral amygdala (cBLA) regions on the maintenance and reinstatement of drug-seeking behavior in rats trained to self-administer 1 mg/kg cocaine under a second order schedule of drug delivery. Both regions of the basolateral amygdala were investigated because they have dissociable effects on cognitive task performance. Results demonstrated that after self-administration training and a period of extinction and abstinence, lidocaine inactivation of the rBLA and cBLA attenuated the reinstatement of drug-seeking behavior induced by cocaine-associated cues examined in conjunction with a single priming injection of cocaine. In contrast, lidocaine inactivation of only the rBLA blocked reinstatement of drug-seeking behavior induced by cocaine-associated cues examined alone. Additional differences were shown during cocaine maintenance testing where inactivation of only the cBLA attenuated drug-seeking behavior. Drug intake was not altered. Thus, the rBLA and cBLA appear to selectively and dissociably regulate drug-seeking behavior under conditions of cocaine abstinence (cue-induced reinstatement) and repeated cocaine use (maintenance), respectively. These findings suggest that the basolateral amygdala may be more functionally heterogeneous than commonly thought for regulating drug-seeking behavior. The basis for this dissociation might be related to neuroanatomical connections of the rBLA and cBLA with segregated, but parallel, corticostriatalpallidothalamic circuits.

Complementary tasks to measure working memory in distinct prefrontal cortex subregions in rats.

Acquisition of odor-guided or visually-guided delayed win-shift behavior was evaluated in rats after lidocaine-induced inactivation within the agranular insular area of the prefrontal cortex (PFC) or the prelimbic area of the PFC. Additional sites and tasks were used to control for neuroanatomical and behavioral specificity of lidocaine inactivation of the agranular insular and prelimbic areas. Results showed that acquisition of the odor-guided delayed win-shift task was dependent on the agranular insular area, whereas acquisition of the visually-guided version was dependent on the prelimbic area. This dissociation suggests that the stimulus modality used is critical for revealing working memory functions of different PFC subregions. The described methods provide a complementary means to study working memory in PFC subregions using a radial-arm maze.

Stimulus-response functions of the lateral dorsal striatum and regulation of behavior studied in a cocaine maintenance/cue reinstatement model in rats.

RATIONALE: To investigate potential neurocognitive mechanisms underlying drug-seeking and drug-taking behavior, the effects of reversible lidocaine-induced inactivation of the lateral dorsal striatum (DST) on behavior studied in a drug maintenance/cue reinstatement model were evaluated. This region of the DST was investigated because it selectively regulates stimulus-response learning that is disrupted by 10 microg of bilaterally infused lidocaine. METHODS: Rats ( n=6) were trained to self-administer 1 mg/kg per infusion cocaine under a second-order schedule of drug delivery. The effects of bilateral lidocaine (30-100 microg) inactivation of the lateral DST were evaluated during drug maintenance tests as well as during tests in which responding was reinstated by cocaine-associated cues presented in combination with a cocaine priming injection. The lower 10 microg dose was used to examine the effects of lidocaine on reinstatement of responding induced by presentation of cues alone. RESULTS: During drug maintenance tests, drug-seeking behavior was significantly increased after inactivation by 100 microg lidocaine. The number of infusions earned did not change. During cue-induced reinstatement tests preceded by a cocaine priming injection, 100 microg lidocaine significantly decreased both drug-seeking behavior and the number of infusion-paired light deliveries earned. During reinstatement tests with cues presented alone, inactivation of the lateral DST by 10 microg lidocaine did not influence either behavior. CONCLUSIONS: These findings suggest that stimulus-response functions of the lateral DST may regulate the dose-related effects of self-administered cocaine because the lidocaine-induced changes in behavior during the maintenance and cocaine priming tests resembled the effects of exposure to increasingly lower doses of cocaine, respectively. Given the lack of an effect of lidocaine during the cues-alone tests, the lateral DST does not appear to regulate drug-seeking behavior per se (i.e., responding maintained by drug-associated cues at times when drug is not available).

Hippocampal memory system function and the regulation of cocaine self-administration behavior in rats.

There is considerable interest in elucidating neurocognitive mechanisms of cocaine addiction. This report focuses on the hippocampal memory system. Using food reward, two cognitive tasks were examined after lidocaine inactivation of the dorsal (dSUB) or ventral (vSUB) subiculum, the primary hippocampal output regions in rats. These tasks were conducted to first identify functionally relevant stereotaxic coordinates within the hippocampal memory system, in order to then examine its role in regulating drug-seeking and drug-taking behavior studied under a contextually discriminable FI 5-min(FR5:S) second-order schedule of cocaine and brief stimulus delivery. Inactivation of the dSUB and vSUB with 10microg lidocaine impaired hippocampal-dependent win-shift performance. Amygdalar-dependant conditioned cue preference, used as a test for behavioral specificity of lidocaine, was not affected following inactivation of either site. Inactivation of the dSUB with 100 microg lidocaine significantly reduced drug-seeking and drug-taking behavior studied during the cocaine self-administration maintenance phase. Following extinction, inactivation of neither the dSUB nor vSUB influenced reinstatement of drug-seeking behavior induced by drug-paired cues presented alone or with a cocaine priming injection. The impairments in win-shift performance are consistent with the spatial processing functions of the dSUB and vSUB, and the reduction in drug-taking behavior is consistent with the non-spatial temporal processing functions of the dSUB. The lack of an effect of dSUB and vSUB inactivation on reinstatement of drug-seeking behavior may relate to the fact that the contextual associations with cocaine were well-practiced at the time of cue reinstatement testing, and therefore, drug-seeking behavior was likely regulated by nonhippocampal-dependent mechanisms.