Validation crisis in animal models of drug addiction: Beyond non-disordered drug use toward drug addiction

In standard drug self-administration settings, animals have no choice than drug use. As a result, serious doubt exists about the interpretation of drug use in experimental animals. Is it symptomatic of an underlying addiction state or merely an expectable response to lack of choice? This incertitude in turn casts a shadow over many behavioral and neurobiological changes that have been well documented in animals following extended drug self-administration. Do they reflect pathological dysfunctions or normal neurobiological adaptations? Here I address these questions by focusing on intravenous cocaine self-administration in the rat as a paradigm example. Overall, available evidence shows that when a valuable behavioral option, even a biologically or physiologically inessential one, is made available during access to cocaine self-administration, most rats readily abstain from cocaine use in favor of the alternative reward regardless of the amount of past cocaine use. Only a small minority of rats continue to self-administer the drug despite the opportunity of making a different choice. This pattern of results (i.e., abstinence in most rats; cocaine preference in few rats) maps well onto what is currently known about the epidemiology of human cocaine addiction. It is thus possible that the minority of cocaine-preferring rats would be homologous to the minority of human cocaine users with a diagnosis of addiction while the remaining majority of abstinent rats would be resilient to cocaine addiction. Choice could represent an objective method of selection of addicted animals for future research on the neurobiological dysfunctions that are hypothesized to underlie cocaine addiction. Other competing interpretations of the same pattern of results are also discussed at the end of this review.     

Validation crisis in animal models of drug addiction: Beyond non-disordered drug use toward drug addiction

In standard drug self-administration settings, animals have no choice than drug use. As a result, serious doubt exists about the interpretation of drug use in experimental animals. Is it symptomatic of an underlying addiction state or merely an expectable response to lack of choice? This incertitude in turn casts a shadow over many behavioral and neurobiological changes that have been well documented in animals following extended drug self-administration. Do they reflect pathological dysfunctions or normal neurobiological adaptations? Here I address these questions by focusing on intravenous cocaine self-administration in the rat as a paradigm example. Overall, available evidence shows that when a valuable behavioral option, even a biologically or physiologically inessential one, is made available during access to cocaine self-administration, most rats readily abstain from cocaine use in favor of the alternative reward regardless of the amount of past cocaine use. Only a small minority of rats continue to self-administer the drug despite the opportunity of making a different choice. This pattern of results (i.e., abstinence in most rats; cocaine preference in few rats) maps well onto what is currently known about the epidemiology of human cocaine addiction. It is thus possible that the minority of cocaine-preferring rats would be homologous to the minority of human cocaine users with a diagnosis of addiction while the remaining majority of abstinent rats would be resilient to cocaine addiction. Choice could represent an objective method of selection of addicted animals for future research on the neurobiological dysfunctions that are hypothesized to underlie cocaine addiction. Other competing interpretations of the same pattern of results are also discussed at the end of this review.     

Withdrawal from extended‐access cocaine self‐administration results in dysregulated functional activity and altered locomotor activity in rats

Much work has focused on determining the consequences of cocaine self‐administration on specific neurotransmitter systems, thus neglecting the global changes that occur. Previous imaging studies have focused on the effects of cocaine self‐administration in the presence of high blood levels of cocaine, but have not determined the functional effects of cocaine self‐administration after cocaine has cleared. Extended‐access cocaine self‐administration, where animals administer cocaine for 6 h each day, results in escalation in the rate of cocaine intake and is believed to model the transition from recreational use to addiction in humans. We aimed to determine the functional changes following acute (48 h) withdrawal from an extended‐access, defined‐intake self‐administration paradigm (5 days, 40 injections/day, 6 h/day), a time point when behavioral changes are present. Using the 2‐[¹⁴C]deoxyglucose method to measure rates of local cerebral glucose metabolism, an indicator of functional activity, we found reductions in circuits related to learning and memory, attention, sleep, and reward processing, which have important clinical implications for cocaine addiction. Additionally, lower levels of functional activity were found in the dorsal raphe and locus coeruleus, suggesting that cocaine self‐administration may have broader effects on brain function than previously noted. These widespread neurochemical reductions were concomitant with substantial behavioral differences in these animals, highlighted by increased vertical activity and decreased stereotypy. These data demonstrate that behavioral and neurochemical impairments following cocaine self‐administration are present in the absence of drug and persist after cocaine has been cleared.     

The motivation to self-administer is increased after a history of spiking brain levels of cocaine

Recent attempts to model the addiction process in rodents have focused on cocaine self-administration procedures that provide extended daily access. Such procedures produce a characteristic loading phase during which blood levels rapidly rise and then are maintained within an elevated range for the duration of the session. The present experiments tested the hypothesis that multiple fast-rising spikes in cocaine levels contribute to the addiction process more robustly than constant, maintained drug levels. Here, we compared the effects of various cocaine self-administration procedures that produced very different patterns of drug intake and drug dynamics on Pmax, a behavioral economic measure of the motivation to self-administer drug. Two groups received intermittent access (IntA) to cocaine during daily 6-h sessions. Access was limited to twelve 5-min trials that alternated with 25-min timeout periods, using either a hold-down procedure or a fixed ratio 1 (FR1). Cocaine levels could not be maintained with this procedure; instead the animals experienced 12 fast-rising spikes in cocaine levels each day. The IntA groups were compared with groups given 6-h FR1 long access and 2-h short access sessions and two other control groups. Here, we report that cocaine self-administration procedures resulting in repeatedly spiking drug levels produce more robust increases in Pmax than procedures resulting in maintained high levels of cocaine. These results suggest that rapid spiking of brain-cocaine levels is sufficient to increase the motivation to self-administer cocaine.     

Incentive and dopamine sensitization produced by intermittent but not long access cocaine self‐administration

The temporal pattern of drug use (pharmacokinetics) has a profound effect on the ability of self‐administered cocaine to produce addiction‐like behavior in rodents, and to change the brain. To further address this issue, we compared the effects of long access (LgA) cocaine self‐administration, which is widely used to model the transition to addiction, with intermittent access (IntA), which is thought to better reflect the pattern of drug use in humans, on the ability of a single, self‐administered injection of cocaine to increase dopamine (DA) overflow in the core of the nucleus accumbens (using in vivo microdialysis), and to produce addiction‐like behavior. IntA experience was more effective than LgA in producing addiction‐like behavior—a drug experience‐dependent increase in motivation for cocaine assessed using behavioral economic procedures, and cue‐induced reinstatement—despite much less total drug consumption. There were no group differences in basal levels of DA in dialysate [DA], but a single self‐administered IV injection of cocaine increased [DA] in the core of the nucleus accumbens to a greater extent in rats with prior IntA experience than those with LgA or limited access experience, and the latter two groups did not differ. Furthermore, high motivation for cocaine was associated with a high [DA] response. Thus, IntA, but not LgA, produced both incentive and DA sensitization. This is consistent with the notion that a hyper‐responsive dopaminergic system may contribute to the transition from casual patterns of drug use to the problematic patterns that define addiction.     

The attribution of incentive salience to a stimulus that signals an intravenous injection of cocaine

A central premise of a number of theories of addiction is that discrete environmental stimuli repeatedly paired with drugs of abuse acquire incentive salience as a result of Pavlovian learning. There is, however, no unequivocal evidence supporting this assumption. Thus, we employed a Pavlovian conditioning procedure known to imbue non-drug reinforcers with incentive salience and extended it to study the effects of intravenous cocaine. Specifically, we examined whether a cue paired with intravenous cocaine administration would come to elicit approach towards it (sign-tracking), even if no behavioral response were required to receive the cue or drug. We found that when a cue was paired with intravenous cocaine delivery (but not when it was unpaired) rats came to approach and investigate the cue, and did so with increasing rapidity. We conclude that Pavlovian learning can imbue drug-paired cues with incentive salience, making them attractive and "wanted" stimuli. Delineating the neurobiological mechanisms responsible for this process will be important for understanding and treating drug addiction.     

Multigenerational and transgenerational effects of paternal exposure to drugs of abuse on behavioral and neural function

Addictions are highly heritable disorders, with heritability estimates ranging from 39% to 72%. Multiple studies suggest a link between paternal drug abuse and addiction in their children. However, patterns of inheritance cannot be explained purely by Mendelian genetic mechanisms. Exposure to drugs of abuse results in epigenetic changes that may be passed on through the germline. This mechanism of epigenetic transgenerational inheritance may provide a link between paternal drug exposure and addiction susceptibility in the offspring. Recent studies have begun to investigate the effect of paternal drug exposure on behavioral and neurobiological phenotypes in offspring of drug‐exposed fathers in rodent models. This review aims to discuss behavioral and neural effects of paternal exposure to alcohol, cocaine, opioids, and nicotine. Although a special focus will be on addiction‐relevant behaviors, additional behavioral effects including cognition, anxiety, and depressive‐like behaviors will be discussed.     

Demand elasticity predicts addiction endophenotypes and the therapeutic efficacy of an orexin/hypocretin‐1 receptor antagonist in rats

Behavioral economics is a powerful, translational approach for measuring drug demand in both humans and animals. Here, we asked if demand for cocaine in rats with limited drug experience could be used to identify individuals most at risk of expressing an addiction phenotype following either long‐ or intermittent access self‐administration schedules, both of which model the transition to uncontrolled drug‐seeking. Because the orexin‐1 receptor antagonist SB‐334867 (SB) is particularly effective at reducing drug‐seeking in highly motivated individuals, we also asked whether demand measured after prolonged drug experience could predict SB efficacy. Demand elasticity (α) measured immediately following acquisition of cocaine self‐administration (‘baseline α’) was positively correlated with α assessed after 2w of long‐ or intermittent access. Baseline α also predicted the magnitude of compulsive responding for cocaine, drug‐seeking in initial abstinence and cued reinstatement following long‐, intermittent‐ or standard short access. When demand was measured after these differential access conditions, α predicted the same addiction endophenotypes predicted by baseline α, as well as primed reinstatement and the emergence of negative emotional mood behavior following abstinence. α also predicted the efficacy of SB, such that high demand rats showed greater reductions in motivation for cocaine following SB compared to low demand rats. Together, these findings indicate that α might serve as a behavioral biomarker to predict individuals most likely to progress from controlled to uncontrolled drug use, and to identify individuals most likely to benefit from orexin‐based therapies for the treatment of addiction.     

PET imaging of dopamine D2 receptors in monkey models of cocaine abuse: genetic predisposition versus environmental modulation

OBJECTIVE: Animals self-administer many of the drugs that humans abuse, including cocaine. This article describes studies using preclinical animal models to differentiate the influences of neurobiological predisposition from environmental modulation of cocaine addiction, including studies from the authors' laboratory using nonhuman primates. METHOD: Addiction is described in terms of vulnerability, maintenance, and abstinence. This review focuses on dopamine receptor function, in particular that of the D2-like receptors, as measured by the noninvasive imaging procedure positron emission tomography. Findings from human studies of addiction and animal models are reviewed. RESULTS: There appears to be an inverse relationship between D2 receptor availability and vulnerability to the reinforcing effects of cocaine. Environmental variables can increase or decrease D2 receptor binding in an orderly fashion, and the resulting changes in D2 function influence the vulnerability to abuse cocaine. In maintenance, chronic cocaine exposure produces decreases in D2 receptor binding, which may be a mechanism that contributes to continued drug use. Finally, during abstinence there are individual differences in rates of recovery of D2 receptor availability. CONCLUSIONS: The goal of the preclinical research described in this review is to achieve a better understanding of individual differences in susceptibility and vulnerability to the reinforcing effects of cocaine. It is clear that the development of novel animal models will extend our understanding of the neurobiological basis of drug addiction to include a greater appreciation of the role of environmental factors in affecting predisposition, mediating continued drug use, and triggering relapse.     

Spontaneous appetence for wheel-running: a model of dependency on physical activity in rat

According to human observations of a syndrome of physical activity dependence and its consequences, we tried to examine if running activity in a free activity paradigm, where rats had a free access to activity wheel, may present a valuable animal model for physical activity dependence and most generally to behavioral dependence. The pertinence of reactivity to novelty, a well-known pharmacological dependence predictor was also tested. Given the close linkage observed in human between physical activity and drugs use and abuse, the influence of free activity in activity wheels on reactivity to amphetamine injection and reactivity to novelty were also assessed. It appeared that (1) free access to wheel may be used as a valuable model for physical activity addiction, (2) two populations differing in activity amount also differed in dependence to wheel-running. (3) Reactivity to novelty did not appeared as a predictive factor for physical activity dependence (4) activity modified novelty reactivity and (5) subjects who exhibited a high appetence to wheel-running, presented a strong reactivity to amphetamine. These results propose a model of dependency on physical activity without any pharmacological intervention, and demonstrate the existence of individual differences in the development of this addiction. In addition, these data highlight the development of a likely vulnerability to pharmacological addiction after intense and sustained physical activity, as also described in man. This model could therefore prove pertinent for studying behavioral dependencies and the underlying neurobiological mechanisms. These results may influence the way psychiatrists view behavioral dependencies and phenomena such as doping in sport or addiction to sport itself.     

Brain-derived neurotrophic factor and its intracellular signaling pathways in cocaine addiction

Cocaine addiction is one of the severest health problems faced by western countries, where there is an increasing prevalence of lifelong abuse. The most challenging aspects in the treatment of cocaine addiction are craving and relapse, especially in view of the fact that, at present, there is a lack of effective pharmacological treatment for the disorder. What is required are new pharmacological approaches based on our current understanding of the neurobiological bases of drug addiction. Within the context of the behavioral and neurochemical actions of cocaine, this paper considers the contribution of brain-derived neurotrophic factor (BDNF) and its main intracellular signaling mechanisms, including mitogen-activated protein kinase/extracellular signal-regulated protein kinase (MAPK/ERK) and phosphatidylinositol 3-kinase (PI3K), in psychostimulant addiction. Repeated cocaine administration leads to an increase in BDNF levels and enhanced activity in the intracellular pathways (PI3K and MAPK/ERK) in the reward-related brain areas, which applies especially several days following withdrawal. It has been hypothesized that these neurochemical changes contribute to the enduring synaptic plasticity that underlies sensitized responses to psychostimulants and drug-conditioned memories leading to compulsive drug use and frequent relapse after withdrawal. Nevertheless, increased BDNF levels could also have a role as a protection factor in addiction. The inhibition of the intracellular pathways, ERK and PI3K, leads to a disruption in sensitized responses and conditioned memories associated with cocaine addiction and suggests new, potential therapeutic strategies to explore in the dependence on psychostimulants.     

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 re-exposed 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.     

Association between the PPP3CC gene, coding for the calcineurin gamma catalytic subunit, and bipolar disorder

Cocaine addiction involves a number of medical, psychological and social problems. Understanding the genetic aetiology of this disorder will be essential for design of effective treatments. Dopamine-beta hydroxylase (DbH) catalyzes the conversion of dopamine to norepinephrine and could, therefore, have an influence on both cocaine action and the basal sensitivity of neurotransmitter systems to cocaine. Recently, the -1021C>T polymorphism have been found to strongly correlated with individual variation in plasma DbH activity. To test the influence of this polymorphism on the susceptibility of cocaine addiction, we decided to genotype it in a sample of 689 cocaine addicts and 832 healthy individuals. Genotypic and allelic analyses did not show any evidence of association with cocaine addiction, even after correcting for the effect of population stratification and other possible confounders. Our results do not support a major role of the -1021C>T polymorphism or the gene itself in the development of cocaine addiction but further examination of other variants within this gene will be necessary to completely rule out an effect.     

A scale-free systems theory of motivation and addiction

Scale-free organizations, characterized by uneven distributions of linkages between nodal elements, describe the structure and function of many life-based complex systems developing under evolutionary pressures. We explore motivated behavior as a scale-free map toward a comprehensive translational theory of addiction. Motivational and behavioral repertoires are reframed as link and nodal element sets, respectively, comprising a scale-free structure. These sets are generated by semi-independent information-processing streams within cortical-striatal circuits that cooperatively provide decision-making and sequential processing functions necessary for traversing maps of motivational links connecting behavioral nodes. Dopamine modulation of cortical-striatal plasticity serves a central-hierarchical mechanism for survival-adaptive sculpting and development of motivational-behavioral repertoires by guiding a scale-free design. Drug-induced dopamine activity promotes drug taking as a highly connected behavioral hub at the expense of natural-adaptive motivational links and behavioral nodes. Conceptualizing addiction as pathological alteration of scale-free motivational-behavioral repertoires unifies neurobiological, neurocomputational and behavioral research while addressing addiction vulnerability in adolescence and psychiatric illness. This model may inform integrative research in defining more effective prevention and treatment strategies for addiction.     

Comparison of acute and chronic neurochemical effects of cocaine and cocaine cues in rhesus monkeys and rodents: focus on striatal and cortical dopamine systems

Preclinical work into the effects of cocaine on mesostriatal and mesocorticolimbic dopamine systems has rightly been dominated by studies in rodent models. From the wealth of data that has resulted from those studies, models of chronic neurobiological adaptations have been developed that might illuminate the cellular and systems bases for the compulsive and self-injurious aspects of addiction. Chronic adaptations of dopaminergic mechanisms often dominate these models. Our studies into the acute and chronic dopaminergic effects of cocaine in non-human primates are compared to important aspects of the larger rodent literature. In some ways there is good concordance, but in others the non-human primate results differ in ways that are more similar to the human literature. This is especially true in regard to sensitization of dopamine systems in response to chronic self-administration. To best evaluate potential models of addiction, it will be important to also consider data from non-human primates as a more proximal animal model to the human condition, particularly in the greater complexity of cortical development.     

How to make a rat addicted to cocaine

Procedures have been developed which provide extremely stable patterns of cocaine self-administration in rats and these have been useful in lesion and drug pretreatment studies aimed at understanding the neurobiology of cocaine reinforcement. The issue now is whether studying the neurobiology of reinforcement is the same as studying the neurobiology of addiction. If the goal is to understand a progressive and deteriorating disorder, then the self-administration procedures should model specific aspects of the progressive stages of the addiction process. Here we review theoretical strategies for modeling the addiction process and present data from a series of experiments from our laboratory showing conditions which produce a progressive change in the motivation to self-administer cocaine in rats. This phenomenon is revealed by an escalation in breakpoints on a progressive ratio schedule. The effect, which is robust and persistent, depends on dose and speed of injection. Interestingly, high drug intake can retard the development of this effect, which we argue indicates that the addiction process has a developmental sequence. Finally, we suggest that specific parameters (dose, price and availability) can be used to examine the transition from recreational use to binge-like intake.     

Reduced grey matter in the posterior insula as a structural vulnerability or diathesis to addiction

A number of neuroimaging studies have shown that drug addiction is associated with morphological differences in several brain areas, including orbito-frontal and limbic structures. Most of these studies have investigated patients with addiction to cocaine. The neurobiological mechanisms which play a role in drug addiction are not fully understood, however, and the causal factors remain under investigation. The present study investigated morphological differences between patients with history of cocaine (N=14) and heroin (N=24) abuse and healthy matched controls (N=24). A 3D T1W MRI scan was acquired for all participants and the grey matter images of each patient group compared with those of controls. A direct comparison of the two addiction groups was also carried out. When compared with controls cocaine dependent patients had lower grey matter values in the left middle occipital gyrus, right putamen and insula, whereas heroin abusers had lower grey matter values in the right insula. The direct comparison between the two addiction groups showed that cocaine abusers had less grey matter in the right posterior cingulate, medio-temporal and cerebellar regions, whereas heroin abusers showed less grey matter in parietal regions on both sides, including postcentral gyrus and inferior parietal lobule. Reduced right posterior insular cortex was commonly found in both cocaine and heroin dependent patients. This morphological difference might represent a structural marker of addiction, which is independent of the discrete regional effects of each psychotropic substance of abuse, and might constitute a possible neurobiological vulnerability or diathesis to addiction. Equally, the discrete structural differences emerging from the direct comparison of cocaine and heroin abusers might reflect the effects of differential drug binding in the brain and/or express a form of neurobiological vulnerability which might explain individual drug choice.     

Modulation of striatal dopamine dynamics by cocaine self‐administration and amphetamine treatment in female rats

Despite decades of research into the neurobiological basis of cocaine abuse, pharmacotherapeutic treatments for cocaine addiction have been largely ineffective. Converging evidence from preclinical research and from outpatient clinical trials suggest that treatment with amphetamine is efficacious in reducing cocaine intake. Although it has been suggested that amphetamine treatment reduces cocaine intake as an agonist replacement therapy, we have shown recently that multiple aspects of dopamine signaling are altered by cocaine self‐administration and returned to pre‐cocaine function by amphetamine treatment in the nucleus accumbens of male rats. Here, we sought to determine if these effects were also evident in female subjects, and across regions of the striatum. Female rats performed 5 days of cocaine self‐administration (1.5 mg kg^?1 inj^?1, 40 inj/day) and were treated with a single amphetamine (0.56 mg/kg) or saline infusion 1 hr prior to killing. We then used ex vivo fast‐scan cyclic voltammetry in the nucleus accumbens core or dorsolateral caudate‐putamen to examine dopamine signaling and cocaine potency. We found that in the nucleus accumbens core, cocaine self‐administration decreased dopamine uptake rate and cocaine potency, and both alterations were restored by amphetamine treatment. In the dorsolateral caudate‐putamen, neither cocaine self‐administration nor amphetamine treatment altered dopamine uptake; however, cocaine potency was decreased by self‐administration and returned to control levels by amphetamine. Together, these findings support a role for amphetamine treatment for cocaine addiction outside of agonist replacement therapy, and suggest that the development of cocaine tolerance is similar across sexes.     

One hour, but not six hours, of daily access to self-administered cocaine results in elevated levels of the dopamine transporter

We have previously shown that brief (1 h) and extended (6 h) daily access to IV cocaine self-administration produce different behavioral and neural consequences following 2 weeks of drug withdrawal. Brief daily access produced stable consumption of the drug and, after withdrawal, a sensitized locomotor response and an enhanced c-Fos labeling to a single cocaine challenge. In contrast, extended daily cocaine self-administration produced escalation of drug consumption over trials but no enhanced behavioral or neurochemical response after withdrawal. Cocaine affects dopaminergic (DA) function by binding to the presynaptic transporter and thereby preventing reuptake of the neurotransmitter-an action thought to be responsible for the drug's reinforcing properties. In an extension of our previous work, the current study, using receptor autoradiography, compared binding (by [3H]WIN35428) of the dopamine transporter (DAT) in animals having experienced either brief or extended daily access to cocaine over 8 days, followed by 14 days of withdrawal. DAT densities were found to increase in the nucleus accumbens core (N.Acc Core) and the dorsal striatum (but not in the N.Acc shell, medial prefrontal cortex (mPFC), or ventral tegmental area (VTA)) of the 1-h, but not 6-h, subjects. In other words, elevations in DAT density were not associated with the 6-h access group, the group that models patterns of drug-use in human addicts, and therefore are likely to be independent of the neuroadaptations that occur in the "addictive" process. Such conclusions are also consistent with brain-imaging studies of human cocaine addicts. Additional research will be needed to identify the specific neural changes relevant to addiction.     

Trait impulsive choice predicts resistance to extinction and propensity to relapse to cocaine seeking: a bidirectional investigation

Despite the strong association between impulsivity and addiction in humans, it is still a matter of debate whether impulsive choice predisposes to, or results from, drug dependence. Furthermore, it is unknown whether treating impulsivity can protect against relapse propensity. Therefore, this study explored the bidirectional relationship between impulsive choice and cocaine taking and seeking in rat behavioral models. In experiment 1, to determine whether impulsive choice predisposes to cocaine taking or seeking, rats were selected based on trait impulsivity in a delayed reward task and subsequently compared on various stages of cocaine self-administration (SA). To examine the consequence of cocaine intake on impulsive choice, impulsivity was monitored once a week throughout various stages of cocaine SA. To determine whether treating impulsive choice can protect against relapse propensity, in experiment 2, impulsive choice was manipulated by pharmacological interventions and cocaine-associated contextual cues. Trait impulsive choice as determined in experiment 1 predicted high extinction resistance and enhanced propensity to context-induced relapse in the cocaine SA model, whereas cocaine intake did not alter impulsive choice. Furthermore, acute changes in impulsive choice were not related to rates of context-induced relapse. Taken together, the current data indicate that trait impulsive choice predicts persistent cocaine seeking during extinction and enhanced propensity to relapse, whereas acute manipulations of impulsive choice had no favorable outcomes on relapse measures. These observations suggest that trait impulsivity can be used as a predictive factor for addiction liability, but treating this impulsivity does not necessarily protect against relapse.