Widespread but regionally specific effects of experimenter- versus self-administered morphine on dendritic spines in the nucleus accumbens, hippocampus, and neocortex of adult rats

We studied the effects of self-administered (SA) vs. experimenter-administered (EA) morphine on dendritic spines in the hippocampal formation (CA1 and dentate), nucleus accumbens shell (NAcc-s), sensory cortex (Par1 and Oc1), medial frontal cortex (Cg3), and orbital frontal cortex (AID) of rats. Animals in the SA group self-administered morphine in 2-h sessions (0.5 mg/kg/infusion, i.v.) for an average of 22 sessions and animals in the EA group were given daily i.v. injections of doses that approximated the total session dose for matched rats in Group SA (average cumulative dose/session of 7.7 mg/kg). Control rats were given daily i.v. infusions of saline. One month after the last treatment the brains were processed for Golgi-Cox staining. In most brain regions (Cg3, Oc1, NAcc-s) morphine decreased the density of dendritic spines, regardless of mode of administration (although to a significantly greater extent in Group SA). However, only SA morphine decreased spine density in the hippocampal formation and only EA morphine decreased spine density in Par1. Interestingly, in the orbital frontal cortex morphine significantly increased spine density in both Groups SA and EA, although to a much greater extent in Group SA. We conclude: 1) Morphine has persistent (at least 1 month) effects on the density of dendritic spines in many brain regions, and on many different types of cells (medium spiny neurons, pyramidal cells, and granule cells); 2) The effect of morphine on spine density (and presumably synaptic organization) varies as a function of both brain region and mode of drug administration; and 3) The ability of morphine to remodel synaptic inputs in a regionally specific manner may account for the many different long-term sequelae associated with opioid use. Synapse 46:271–279, 2002. © 2002 Wiley-Liss, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/34996/1/10146_ftp.pd

Opposite Effects of Amphetamine Self-administration Experience on Dendritic Spines in the Medial and Orbital Prefrontal Cortex

We studied the long-term effects of amphetamine self-administration experience (or sucrose reward training) on dendritic morphology (spine density) in nucleus accumbens (Nacc), medial (MPC) and orbital prefrontal cortex (OFC), and hippocampus (CA1 and dentate). Independent groups of rats were trained under a continuous schedule of reinforcement to nose-poke for infusions of amphetamine (0.125 mg/kg/inf) or to receive sucrose pellets during 2 h daily test sessions for 14-20 days. One month after the last training session, the brains were collected and processed for Golgi-Cox staining. We found that: (i) amphetamine self-administration experience selectively increased spine density on medium spiny neurons in the Nacc and on pyramidal neurons in the MPC; (ii) in contrast, amphetamine self-administration decreased spine density in the OFC, whereas sucrose-reward training increased spine density; and (iii) both amphetamine self-administration and sucrose-reward experience increased spines in the CA1, but had no effect in the dentate gyrus. Thus, amphetamine self-administration experience produces long-lasting and regionally-selective morphological alterations in rat forebrain - alterations that may underlie some of the persistent psychomotor, cognitive and motivational consequences of chronic drug exposure

Neural and Behavioral Plasticity Associated with the Transition from Controlled to Escalated Cocaine Use

Background. Rats given extended access to cocaine develop several symptoms of addiction, including a gradual escalation of drug intake, whereas rats given limited access do not. We asked here whether extended access to cocaine also produces drug-induced sensitization, a form of neurobehavioral plasticity implicated in addiction. Methods. Rats were given limited (1 hour/session) or extended access (6 hours/session) to self-administered cocaine. Following a period of abstinence, rats were selected at random for assessment of their psychomotor response to cocaine or drug-seeking during extinction or for anatomic studies. Results. When reexposed to cocaine, rats allowed extended drug access showed greater drug-seeking behavior and were hypersensitive (sensitized) to the psychomotor activating effects of cocaine compared with rats given limited access. Extended access to cocaine was also associated with a greater increase in the density of dendritic spines on neurons specifically in the core of the nucleus accumbens (and not in the shell or medial or orbital frontal cortex). Conclusions. The transition from stable to escalated cocaine use, a hallmark of addiction, is associated with especially robust behavioral sensitization and synaptic reorganization in the core of the nucleus accumbens

Amphetamine-Induced Changes in Dendritic Morphology in Rat Forebrain Correspond to Associative Drug Conditioning Rather than Nonassociative Drug Sensitization

Background: Systemic exposure to amphetamine (AMPH) leads to a number of long-lasting neuroadaptations including changes in dendritic morphology in rat forebrain. It remains unknown whether these changes relate to associative drug conditioning or to nonassociative drug sensitization, two forms of plasticity produced by systemic exposure to AMPH.Methods: We compared the behavioral, neuronal, and morphologic consequences of exposing rats to intraperitoneal (IP) AMPH to those of exposure to AMPH applied to the ventral tegmental area (VTA), infusions that sensitize AMPH-induced locomotion and nucleus accumbens (NAcc) DA overflow but do not produce drug conditioning.Results: Both IP and VTA AMPH exposure sensitized locomotion and NAcc DA overflow, but only IP AMPH exposure produced conditioned locomotion. mportantly, whereas IP AMPH exposure increased spine density and dendritic length and branching in the NAcc, exposure to VTA AMPH produced the opposite effects. A similar differentiation of effects was observed in cortical areas. Conclusions: Together these findings suggest that the morphological changes seen following IP AMPH exposure reflect associative drug conditioning rather than nonassociative drug sensitization. The decreases observed in the NAcc of VTA AMPH exposed rats may reflect the inability of these infusions to support conditioning