Anticipation of incentive gain

Flaherty, Charles F.; Checke, Susan

doi:10.3758/bf03212267

Cited by 159 publications

(175 citation statements)

References 27 publications

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“…Studies were not designed to distinguish the mechanisms responsible for reductions in home-cage or predeprivation chow intake. However, several findings support the interpretation that chow hypophagia at the first feeder was a form of anticipatory negative contrast (Flaherty and Checke, 1982;Flaherty and Rowan, 1986;Flaherty et al, 1995) and not energy homeostatic compensation for accruing weight gain, lasting satiety, or successive negative contrast. First, there was no concurrent or prospective relation between differences in weight gain and the magnitude of chow hypophagia (unlike strong individual differences seen in chow hypophagia).…”

Section: Discussionmentioning

confidence: 68%

“…Such a learned change in food acceptance may increase risk for body weight dysregulation and eating disorders because of the increased role placed on sensoryhedonic, rather than nutritional, properties of food for controlling intake (Wardle et al, 2001). Perhaps an analog of this learned change in food acceptance, negative contrast in rodents refers to the hypophagia of an otherwise acceptable tastant that results from having predictably received access to a more preferred substance either immediately before (successive negative contrast) or subsequent to (anticipatory negative contrast) that substance (Flaherty and Checke, 1982;Flaherty and Rowan, 1986;Flaherty et al, 1995). Contrast effects have been studied previously using limitedly available (3-5 min) sweet solutions in weight-restricted rats, but have not yet been well-studied vis-à-vis day-to-day food acceptance/intake in subjects' self-determining body weight.…”

Section: Introductionmentioning

confidence: 99%

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Opioid-Dependent Anticipatory Negative Contrast and Binge-Like Eating in Rats with Limited Access to Highly Preferred Food

Cottone

Sabino

Steardo

et al. 2007

Neuropsychopharmacol

135

149

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Binge eating and an increased role for palatability in determining food intake are abnormal adaptations in feeding behavior linked to eating disorders and body weight dysregulation. The present study tested the hypothesis that rats with limited access to highly preferred food would develop analogous opioid-dependent learned adaptations in feeding behavior, with associated changes in metabolism and anxiety-like behavior. For this purpose, adolescent female Wistar rats were daily food deprived (2 h) and then offered 10-min access to a feeder containing chow followed sequentially by 10-min access to a different feeder containing either chow (chow/chow; n ¼ 7) or a highly preferred, but macronutrient-comparable, sucrose-rich diet (chow/preferred; n ¼ 8). Chow/preferred-fed rats developed binge-like hyperphagia of preferred diet from the second feeder and anticipatory chow hypophagia from the first feeder with a time course suggesting associative learning. The feeding adaptations were dissociable in onset, across individuals, and in their dose-response to the opioid-receptor antagonist nalmefene, suggesting that they represent distinct palatability-motivated processes. Chow/preferred-fed rats showed increased anxiety-like behavior in relation to their propensity to binge as well as increased feed efficiency, body weight, and visceral adiposity. Chow/preferred-fed rats also had increased circulating leptin levels and decreased growth hormone and 'active' ghrelin levels. Thus, the short-term control of food intake in rats with restricted access to highly preferred foods comes to rely more on hedonic, rather than nutritional, properties of food, through associative learning mechanisms. Such rats show changes in ingestive, metabolic, endocrine, and anxiety-related measures, which resemble features of binge eating disorders or obesity.

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Section: Discussionmentioning

confidence: 68%

Section: Introductionmentioning

confidence: 99%

Opioid-Dependent Anticipatory Negative Contrast and Binge-Like Eating in Rats with Limited Access to Highly Preferred Food

Cottone

Sabino

Steardo

et al. 2007

Neuropsychopharmacol

135

149

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“…Several studies, using both response-dependent (Williams, 1976a(Williams, , 1979(Williams, , 1981Williams & Wixted, 1986;Wilton & Gay, 1969) and response-independent (Farley , 1980; Williams, 1976b) schedules have demonstrated that a major portion of the contrast effect in a multiple schedule is produced by variation in the reinforcement rate following a target component. Moreover, other investigators , using procedures very different from free-operant multiple schedules, have obtained similar results (Bacotti, 1976;Flaherty & Checke, 1982;Flaherty & Rowan , 1985. A critical issue raised by these findings is the mechanism producing such a contrast effect.…”

supporting

confidence: 49%

Component transition and anticipatory contrast

Williams

1988

Bull. Psychon. Soc.

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Previous research has demonstrated that contrast effects in multiple schedules occur because of variation in the reinforcement rate following the target components (anticipatory contrast). The present study assessed whether the contingency for transition to the following schedule was an important variable, on the premise that the discriminative cue for the following schedule should be a conditioned reinforcer that should suppress behavior when presented on a responseindependent basis. Strong contrast effects occurred even when the transition to the following schedule was response dependent, and these effects were comparable to those normally obtained with response-independent transitions. Several studies, using both response-dependent (Williams, 1976a(Williams, , 1979(Williams, , 1981Williams & Wixted, 1986;Wilton & Gay, 1969) and response-independent (Farley , 1980; Williams, 1976b) schedules have demonstrated that a major portion of the contrast effect in a multiple schedule is produced by variation in the reinforcement rate following a target component. Moreover, other investigators , using procedures very different from free-operant multiple schedules, have obtained similar results (Bacotti, 1976;Flaherty & Checke, 1982;Flaherty & Rowan , 1985. A critical issue raised by these findings is the mechanism producing such a contrast effect. That is, is the effect (hereafter referred to as anticipatory contrast) adequately characterized as the "primitive" result of the relative reinforcement rate in the target component versus that which follows, or is it possible to identify some more molecular underlying process?Previous research has attempted to identify the attribute of the following source of reinforcement that produced anticipatory contrast. Williams (1979 , Experiment 2) presented pigeons with two separate target components, one of which was followed by a higher valued schedule and the other by extinction (EXT). When these two different following schedules were cued by different discriminative stimuli, large anticipatory contrast effects were observed; that is, response rates were higher in the target component followed by EXT. But when the same cue was used for the two different following schedules, resulting in high response rates in both the higher valued schedule and EXT, anticipatory contrast quickly disappeared . This finding demonstrates that it is not simply the occurrence or nonoccurrence of reinforcement in the following component that is the critical variable. Instead, anticipatory contrast seems to depend upon the "value" of the stimulus in the following component, where value is assessed by the response rate in the presence of the stimulus. One interpretation of such effects of stimulus value assumes that the stimulus correlated with the following schedule possesses conditioned reinforcement properties. It is then possible to view a multiple schedule as similar to other procedures in which behavior is suppressed by the presentation of response-independent reinforcement (e.g., Rachlin & Baum, ...

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“…While it is the case that rats clearly avoid intake of a taste cue when paired with a putatively aversive US, such as LiCl, for example, in 1982 Flaherty and Checke [37] reported that rats also avoid intake of a saccharin CS when paired, in once daily sessions, with a highly preferred 32% sucrose solution. This phenomenon was referred to as an anticipatory contrast effect because reduced intake of the saccharin cue was thought to be due to anticipation of the availability of the preferred sucrose reward in the very near future.…”

Section: The Model: Experimenter Delivered Drugmentioning

confidence: 99%

Reward comparison: the Achilles’ heel and hope for addiction

Grigson

2008

Drug Discovery Today: Disease Models

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In the words of the late Charles Flaherty, reward comparison is commonplace. Rats and man, it appears, compare all rewards and this capacity likely contributes to our ability to select the most appropriate reward/behavior (food, water, salt, sex), at the most ideal level (e.g., a certain sweetness), at any given time. A second advantage of our predisposition for reward comparison is that the availability of rich alternative rewards can protect against our becoming addicted to any single reward/behavior. Thus, the potential protective effects of natural rewards/enrichment are addressed. Despite this, behavior can become inflexible when, through the development of addiction, stress, drug, or cues elicit craving, withdrawal, and ultimately, drug-seeking. Drug-seeking corresponds with a 'window of inopportunity', when even potent natural rewards have little or no impact on behavior. During this time, there is a unitary solution to the need state, and that solution is drug. The present animal model explores this 'window of inopportunity' when natural rewards are devalued and drug-seeking is engaged and considers a mode of possible intervention.

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Anticipation of incentive gain

Cited by 159 publications

References 27 publications

Opioid-Dependent Anticipatory Negative Contrast and Binge-Like Eating in Rats with Limited Access to Highly Preferred Food

Opioid-Dependent Anticipatory Negative Contrast and Binge-Like Eating in Rats with Limited Access to Highly Preferred Food

Component transition and anticipatory contrast

Reward comparison: the Achilles’ heel and hope for addiction

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