Acute treatment with the 5-HT 1A receptor agonist 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) or chronic environmental enrichment (EE) hasten behavioral recovery after experimental traumatic brain injury (TBI). The aim of this study was to determine if combining these interventions would confer additional benefit. Anesthetized adult male rats received either a cortical impact or sham injury followed 15 min later by a single intraperitoneal injection of 8-OH-DPAT (0.5 mg/kg) or saline vehicle (1.0 mL/kg) and then randomly assigned to either enriched or standard (STD) housing. Behavioral assessments were conducted utilizing established motor and cognitive tests on post-injury days 1-5 and 14-18, respectively. Hippocampal CA 1 /CA 3 neurons were quantified at 3 weeks. Both 8-OH-DPAT and EE attenuated CA 3 cell loss. 8-OH-DPAT enhanced spatial learning in a Morris water maze (MWM) as revealed by differences between the TBI+8-OH-DPAT+STD and TBI+VEHICLE+STD groups (P=0.0014). EE improved motor function as demonstrated by reduced time to traverse an elevated narrow beam in both the TBI+8-OH-DPAT+EE and TBI+VEHICLE +EE groups vs. the TBI+VEHICLE+STD group (P=0.0007 and P=0.0016, respectively). EE also facilitated MWM learning as evidenced by both the TBI+8-OH-DPAT+EE and TBI+VEHICLE+EE groups locating the escape platform quicker than the TBI+VEHICLE+STD group (P's<0.0001). MWM differences were also observed between the TBI+8-OH-DPAT+EE and TBI+8-OH-DPAT +STD groups (P=0.0004) suggesting that EE enhanced the effect of 8-OH-DPAT. However, there was no difference between the TBI+8-OH-DPAT+EE and TBI+VEHICLE+EE groups. These data replicate previous results from our laboratory showing that both a single systemic administration of 8-OH-DPAT and EE improve recovery after TBI and extend those findings by elucidating that the combination of treatments in this particular paradigm did not confer additional benefit. One explanation for the lack of an additive effect is that EE is a very effective treatment and thus there is very little room for 8-OH-DPAT to confer additional statistically significant improvement.
Several studies have shown that housing rats in an enriched environment (EE) after traumatic brain injury (TBI) improves functional and histological outcome. The typical EE includes exploratory, sensory, and social components in cages that are often vastly larger than standard (STD) housing. It is uncertain, however, whether a single or specific component is sufficient to confer these benefits after TBI, or if all, perhaps in an additive or synergistic manner, are necessary. To clarify this ambiguity, anesthetized adult male rats were subjected to either a controlled cortical impact or sham injury, and then were randomly assigned to five different housing paradigms: (1) EE (typical), (2) EE (-social), (3) EE (-stimuli), (4) STD (typical), and (5) STD (+stimuli). Motor and cognitive function were assessed using conventional motor (beam-balance/traversal) and cognitive (spatial learning in a Morris water maze) tests on postoperative days 1-5 and 14-19, respectively, and cortical lesion volume and CA1/CA3 cell loss were quantified at 3 weeks. No significant differences were observed among the sham groups in any comparison and thus their data were pooled (i.e., SHAM). In the TBI groups, typical EE improved beam-balance versus both STD (+stimuli) and EE (-social), it facilitated the acquisition of spatial learning and memory retention versus all other housing conditions (p < 0.003), and it reduced lesion volume and CA3 cell loss versus STD (typical) housing. While rats in the three atypical EE conditions exhibited slightly better cognitive performance and histological protection versus the typical STD group, the overall effects were not significant. These data suggest that exposing TBI rats to any of the three components individually may be more advantageous than no enrichment, but only exposure to typical EE yields optimal benefits.
A powerful convergence of genetics, neuroimaging and epidemiological research has identified biological pathways mediating individual differences in complex behavioral processes and related risk for disease. Orthologous genetic variation in non-human primates represents a unique opportunity to characterize the detailed molecular and cellular mechanisms which bias behaviorally- and clinically-relevant brain function. We report that a rhesus macaque orthologue of a common polymorphism of the serotonin transporter gene (rh5-HTTLPR) has strikingly similar effects on behavior and brain morphology to those in humans. Specifically, the rh5-HTTLPR Short allele broadly impacts cognitive choice behavior and brain morphology without observably affecting 5-HT transporter or 5-HT1A concentrations in vivo. Collectively, our findings indicate that 5-HTTLPR-associated behavioral effects reflect genotype-dependent biases in cortical development rather than static differences in serotonergic signaling mechanisms. Moreover, these data highlight the vast potential of non-human primate models in advancing our understanding of human genetic variation impacting behavior and neuropsychiatric disease liability.
Cocaine users display a wide range of cognitive impairments. Because treatment outcome is dependent on baseline cognitive ability, it is clinically important to understand the underlying neurobiology of these deficits. Therefore, it is crucial to determine whether cocaine exposure by itself is an etiological factor, and if so, to determine the overall nature of cognitive deficits associated with cocaine use. This will help to guide therapeutic approaches that address cognitive components of cocaine use in order to improve treatment outcome. We used rhesus monkeys in a longitudinal study in which 14 animals were characterized prior to assignment to matched control (n=6) and cocaine self-administration (n=8) groups. Self-administration took place on four consecutive days/week over nine months, with a maximum (and typical) daily cumulative intake of 3.0 mg/kg. Weekly cognitive assessments (total of 36) were conducted following a 72 hour drug free period. We employed a stimulus discrimination task with reversal to evaluate associative learning and the cognitive control/flexibility needed to adapt to changes in reward contingencies. Following extended self-administration, initial accuracy on the stimulus discrimination indicated intact associative learning. However, animals were impaired at maintaining high levels of accuracy needed to reach criterion and initiate the reversal. Increasing the reward contrast between stimuli permitted evaluation of reversal performance, and revealed striking deficits in the cocaine group. Impairments in visual working memory were also observed using a delayed-match-to-sample task. These results suggest a combination of generalized, possibly attentional, impairments, along with a more specific cognitive control impairment implicating orbitofrontal cortex dysfunction.
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