Your search keyword '"Bissonette, Gregory B."' showing total 6 results

1. Prior Cocaine Self-Administration Increases Response-Outcome Encoding That Is Divorced from Actions Selected in Dorsal Lateral Striatum.

Author

Burton, Amanda C., Bissonette, Gregory B., Zhao, Adam C., Patel, Pooja K., and Roesch, Matthew R.

Subjects

*DRUG abuse, *LABORATORY rats, *DECISION making, *NEURONS, *NEUROSCIENCES

Abstract

Dorsal lateral striatum (DLS) is a highly associative structure that encodes relationships among environmental stimuli, behavioral responses, and predicted outcomes. DLS is known to be disrupted after chronic drug abuse; however, it remains unclear what neural signals in DLS are altered. Current theory suggests that drug use enhances stimulus-response processing at the expense of response- outcome encoding, but this has mostly been tested in simple behavioral tasks. Here, we investigated what neural correlates in DLS are affected by previous cocaine exposure as rats performed a complex reward-guided decision-making task in which predicted reward value was independently manipulated by changing the delay to or size of reward associated with a response direction across a series of trial blocks. After cocaine self-administration, rats exhibited stronger biases toward higher-value reward and firing in DLS more strongly represented action- outcome contingencies independent from actions subsequently taken rather than outcomes predicted by selected actions (chosen-outcome contingencies) and associations between stimuli and actions (stimulus-response contingencies). These results suggest that cocaine self-administration strengthens action- outcome encoding in rats (as opposed to chosen-outcome or stimulus- response encoding), which abnormally biases behavior toward valued reward when there is a choice between two options during rewardguided decision-making. [ABSTRACT FROM AUTHOR]

Published

2017

2. Rule encoding in dorsal striatum impacts action selection.

Author

Bissonette, Gregory B., Roesch, Matthew R., and Dalley, Jeffrey

Subjects

*PREFRONTAL cortex, *BEHAVIORAL research, *MENTAL illness, *COGNITIVE ability, *PHARMACOLOGY, *PHYSIOLOGY

Abstract

Cognitive flexibility is a hallmark of prefrontal cortical (PFC) function yet little is known about downstream area involvement. The medial dorsal striatum (mDS) receives major projections from the PFC and is uniquely situated to perform the integration of responses with rule information. In this study, we use a novel rule shifting task in rats that mirrors non-human primate and human studies in its temporal precision and counterbalanced responses. We record activity from single neurons in the mDS while rats switch between different rules for reward. Additionally, we pharmacologically inactivate mDS by infusion of a baclofen/muscimol cocktail. Inactivation of mDS impaired the ability to shift to a new rule and increased the number of regressive errors. While recording in mDS, we identified neurons modulated by direction whose activity reflected the conflict between competing rule information. We show that a subset of these neurons was also rule selective, and that the conflict between competing rule cues was resolved as behavioural performance improved. Other neurons were modulated by rule, but not direction. These neurons became selective before behavioural performance accurately reflected the current rule. These data provide an additional locus for investigating the mechanisms underlying behavioural flexibility. Converging lines of evidence from multiple human psychiatric disorders have implicated dorsal striatum as an important and understudied neural substrate of flexible cognition. Our data confirm the importance of mDS, and suggest a mechanism by which mDS mediates abstract cognition functions. [ABSTRACT FROM AUTHOR]

Published

2015

3. Ventral Striatum Lesions Enhance Stimulus and Response Encoding in Dorsal Striatum.

Author

Burton, Amanda C., Bissonette, Gregory B., Lichtenberg, Nina T., Kashtelyan, Vadim, and Roesch, Matthew R.

Subjects

*NEOSTRIATUM, *DRUG abuse, *NEURAL stimulation, *LABORATORY rats, *DECISION making, *DRUG addiction

Abstract

Background: The development of addiction is thought to reflect a transition from goal-directed to stimulus-response driven behavior, functions attributed to ventral (VS) and dorsal striatum (DS), respectively. In line with this theory, neuroadaptations that occur during prolonged drug use progress from VS to DS. Here we ask if VS dysfunction alone, independent of drug use, can affect neural selectivity in DS. Methods: To address this issue, we recorded from single neurons in DS while rats performed an odor-guided choice task for differently valued rewards in rats with and without unilateral VS lesions. In a separate group of animals, we used bilateral VS lesions to determine if VS was critical for performance on this task. Results: We describe data showing that unilateral lesions of VS enhance neural representations in DS during performance of a task that is dependent on VS. Furthermore, we show that VS is critical for reward-guided decision-making initially, but that rats regain function after several days. Conclusions: These results suggest that loss of VS function, independent of chronic drug use, can trigger stronger encoding in DS in a reward-guided decision-making task and that the transition from VS to DS governed behavior observed in addiction might be due, in part, to initial loss of VS function. [ABSTRACT FROM AUTHOR]

Published

2014

4. Separate Populations of Neurons in Ventral Striatum Encode Value and Motivation

Author

Bissonette, Gregory B., Burton, Amanda C., Gentry, Ronny N., Goldstein, Brandon L., Hearn, Taylor N., Barnett, Brian R., Kashtelyan, Vadim, and Roesch, Matthew R.

Subjects

*NEURONS, *COGNITIVE neuroscience, *ANIMAL cognition, *NEUROPHYSIOLOGY, *NEUROPSYCHOLOGY, *ANIMAL models in research, *CELL populations

Abstract

Neurons in the ventral striatum (VS) fire to cues that predict differently valued rewards. It is unclear whether this activity represents the value associated with the expected reward or the level of motivation induced by reward anticipation. To distinguish between the two, we trained rats on a task in which we varied value independently from motivation by manipulating the size of the reward expected on correct trials and the threat of punishment expected upon errors. We found that separate populations of neurons in VS encode expected value and motivation. [ABSTRACT FROM AUTHOR]

Published

2013

5. Previous Cocaine Exposure Makes Rats Hypersensitive to Both Delay and Reward Magnitude.

Author

Roesch, Matthew R., Takahashi, Yuji, Gugsa, Nishan, Bissonette, Gregory B., and Schoenbaum, Geoffrey

Subjects

COCAINE, LABORATORY rats, STIMULANTS, DRUGS of abuse, NEUROSCIENCES

Abstract

Animals prefer an immediate over a delayed reward, just as they prefer a large over a small reward. Exposure to psychostimulants causes long-lasting changes in structures critical for this behavior and might disrupt normal time-discounting performance. To test this hypothesis, we exposed rats to cocaine daily for 2 weeks (30 mg/kg, i.p.). Approximately 6 weeks later, we tested them on a variant of a time-discounting task, in which the rats responded to one of two locations to obtain reward while we independently manipulated the delay to reward and reward magnitude. Performance did not differ between cocaine-treated and saline-treated (control) rats when delay lengths and reward magnitudes were equal at the two locations. However, cocaine-treated rats were significantly more likely to shift their responding when we increased the delay or reward size asymmetrically. Furthermore, they were slower to respond and made more errors when forced to the side associated with the lower value. We conclude that previous exposure to cocaine makes choice behavior hypersensitive to differences in the time to and size of available rewards, consistent with a general effect of cocaine exposure on reward valuation mechanisms. [ABSTRACT FROM AUTHOR]

Published

2007

6. Attention-Related Pearce-Kaye-Hall Signals in Basolateral Amygdala Require the Midbrain Dopaminergic System

Author

Esber, Guillem R., Roesch, Matthew R., Bali, Shreya, Trageser, Jason, Bissonette, Gregory B., Puche, Adam C., Holland, Peter C., and Schoenbaum, Geoffrey

Subjects

*AMYGDALOID body, *DOPAMINERGIC mechanisms, *MESENCEPHALON, *ATTENTION, *NEURAL transmission, *EVOKED potentials (Electrophysiology)

Abstract

Background: Neural activity in basolateral amygdala has recently been shown to reflect surprise or attention as predicted by the Pearce-Kaye-Hall model (PKH)—an influential model of associative learning. Theoretically, a PKH attentional signal originates in prediction errors of the kind associated with phasic firing of dopamine neurons. This requirement for prediction errors, coupled with projections from the midbrain dopamine system into basolateral amygdala, suggests that the PKH signal in amygdala may depend on dopaminergic input. Methods: To test this, we recorded single unit activity in basolateral amygdala in rats with 6-hydroxydopamine or sham lesions of the ipsilateral midbrain region. Neurons were recorded as the rats performed a task previously used to demonstrate both dopaminergic reward prediction errors and attentional signals in basolateral amygdala neurons. Results: We found that neurons recorded in sham lesioned rats exhibited the same attention-related PKH signal observed in previous studies. By contrast, neurons recorded in rats with ipsilateral 6-hydroxydopamine lesions failed to show attentional signaling. Conclusions: These results indicate a linkage between the neural instantiations of the basolateral complex of the amygdala attentional signal and dopaminergic prediction errors. Such a linkage would have important implications for understanding both normal and aberrant learning and behavior, particularly in diseases thought to have a primary effect on dopamine systems, such as addiction and schizophrenia. [ABSTRACT FROM AUTHOR]

Published

2012