Jennifer E. Klebaur scite author profile

Previous work has shown that individual differences in locomotor activity in an inescapable novel environment can predict acquisition of amphetamine self-administration. The current study examined whether individual differences in approach to novelty in a free choice test could also predict amphetamine self-administration. Further, the current study examined whether individual differences in either free choice or inescapable novelty tests could predict responding for a nondrug reinforcer (sucrose) in the presence and absence of amphetamine. Male and female rats were first tested for their response to free choice novelty (playground maze and novelty-induced place preference tests) and inescapable novelty. They were then tested for acquisition of sucrose-reinforced responding, amphetamine-induced changes in maintenance of sucrose-reinforced responding, and amphetamine self-administration. Based on the inescapable novelty test, acquisition of sucrose-reinforced responding was more rapid in male high responders (HR) compared to low responders (LR). This effect in males did not generalize to females. None of the novelty tests predicted the ability of amphetamine to decrease sucrose-maintained responding. However, using the inescapable novelty test, both male and female HRs self-administered more amphetamine than LRs within the dose range tested (0.03-0.16mg/ kg/infusion). Neither the playground maze nor the novelty-induced place preference test predicted amphetamine self-administration. These results indicate that responses to free choice novelty and inescapable novelty predict different components of amphetamine-induced behavior. O 2001 Lippincott Williams & Wilkins.

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Environmental enrichment decreases intravenous self-administration of amphetamine in female and male rats

Bardo

et al. 2001

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Individual Differences in Novelty Seeking on the Playground Maze Predict Amphetamine Conditioned Place Preference

Klebaur

Bardo

1999

Pharmacology Biochemistry and Behavior

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Exposure to novel environmental stimuli decreases amphetamine self-administration in rats.

Klebaur¹,

Phillips²,

Kelly³

et al. 2001

Experimental and Clinical Psychopharmacology

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Researchers examined whether exposure to novel environmental stimuli reduces drug self-administration. Rats were trained to self-administer amphetamine on a fixed ratio (FR) 5 schedule of reinforcement and then were exposed to novel stimuli during the session. Responding was significantly decreased with exposure to novelty but returned to baseline levels on intervening nonexposure sessions. In 2 subsequent experiments, rats were exposed to novel plastic objects prior to the session. Immediately following exposure, rats were allowed to self-administer amphetamine on an FR 1 schedule, which was increased gradually to an FR 5 either using predetermined increments or on the basis of performance criteria. Exposure to the novel objects significantly decreased acquisition of amphetamine self-administration in both situations. Results suggest that exposure to novel environmental stimuli may be effective at reducing drug self-administration.

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(−)-Nornicotine Partially Substitutes for (+)-Amphetamine in a Drug Discrimination Paradigm in Rats

Bardo

Bevins

Klebaur

et al. 1997

Pharmacology Biochemistry and Behavior

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