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5. Spatial Representations in Rat Orbitofrontal Cortex.

Author

Wikenheiser, Andrew M, Gardner, Matthew PH, Mueller, Lauren E, and Schoenbaum, Geoffrey

Subjects
Neurosciences, Behavioral and Social Science, Basic Behavioral and Social Science, Mental Health, Neurological, Mental health, Animals, Behavior, Animal, Brain Mapping, Electrocorticography, Male, Neurons, Prefrontal Cortex, Rats, Rats, Long-Evans, Spatial Behavior, cognitive map, grid cells, hippocampus, orbitofrontal cortex, place cells, rat, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery
Abstract

The orbitofrontal cortex (OFC) and hippocampus share striking cognitive and functional similarities. As a result, both structures have been proposed to encode "cognitive maps" that provide useful scaffolds for planning complex behaviors. However, while this function has been exemplified by spatial coding in neurons of hippocampal regions-particularly place and grid cells-spatial representations in the OFC have been investigated far less. Here we sought to address this by recording OFC neurons from male rats engaged in an open-field foraging task like that originally developed to characterize place fields in rodent hippocampal neurons. Single-unit activity was recorded as rats searched for food pellets scattered randomly throughout a large enclosure. In some sessions, particular flavors of food occurred more frequently in particular parts of the enclosure; in others, only a single flavor was used. OFC neurons showed spatially localized firing fields in both conditions, and representations changed between flavored and unflavored foraging periods in a manner reminiscent of remapping in the hippocampus. Compared with hippocampal recordings taken under similar behavioral conditions, OFC spatial representations were less temporally reliable, and there was no significant evidence of grid tuning in OFC neurons. These data confirm that OFC neurons show spatial firing fields in a large, two-dimensional environment in a manner similar to hippocampus. Consistent with the focus of the OFC on biological meaning and goals, spatial coding was weaker than in hippocampus and influenced by outcome identity.SIGNIFICANCE STATEMENT The orbitofrontal cortex (OFC) and hippocampus have both been proposed to encode "cognitive maps" that provide useful scaffolds for planning complex behaviors. This function is exemplified by place and grid cells identified in hippocampus, the activity of which maps spatial environments. The current study directly demonstrates very similar, though not identical, spatial representatives in OFC neurons, confirming that OFC-like hippocampus-can represent a spatial map under the appropriate experimental conditions.

Published
2021

7. Past experience shapes the neural circuits recruited for future learning

Author

Sharpe, Melissa J, Batchelor, Hannah M, Mueller, Lauren E, Gardner, Matthew PH, and Schoenbaum, Geoffrey

Subjects
Neurosciences, Behavioral and Social Science, Mental Health, Underpinning research, 1.2 Psychological and socioeconomic processes, Mental health, Animals, Conditioning, Classical, Cues, Fear, Female, GABAergic Neurons, Hypothalamic Area, Lateral, Learning, Male, Neural Pathways, Rats, Rats, Long-Evans, Rats, Transgenic, Reward, Psychology, Cognitive Sciences, Neurology & Neurosurgery
Abstract

Experimental research controls for past experience, yet prior experience influences how we learn. Here, we tested whether we could recruit a neural population that usually encodes rewards to encode aversive events. Specifically, we found that GABAergic neurons in the lateral hypothalamus (LH) were not involved in learning about fear in naïve rats. However, if these rats had prior experience with rewards, LH GABAergic neurons became important for learning about fear. Interestingly, inhibition of these neurons paradoxically enhanced learning about neutral sensory information, regardless of prior experience, suggesting that LH GABAergic neurons normally oppose learning about irrelevant information. These experiments suggest that prior experience shapes the neural circuits recruited for future learning in a highly specific manner, reopening the neural boundaries we have drawn for learning of particular types of information from work in naïve subjects.

Published
2021

11. Cracking and Packing Information about the Features of Expected Rewards in the Orbitofrontal Cortex.

Author

Akihiro Shimbo, Takahashi, Yuji K., Langdon, Angela J., Stalnaker, Thomas A., and Schoenbaum, Geoffrey

Subjects
REWARD (Psychology), PREFRONTAL cortex, FLAVOR, NEURONS, DOPAMINE
Abstract

The orbitofrontal cortex (OFC) is crucial for tracking various aspects of expected outcomes, thereby helping to guide choices and support learning. Our previous study showed that the effects of reward timing and size on the activity of single units in OFC were dissociable when these attributes were manipulated independently (Roesch et al., 2006). However, in real-life decision-making scenarios, outcome features often change simultaneously, so here we investigated how OFC neurons in male rats integrate information about the timing and identity (flavor) of reward and respond to changes in these features, according to whether they were changed simultaneously or separately. We found that a substantial number of OFC neurons fired differentially to immediate versus delayed reward and to the different reward flavors. However, contrary to the previous study, selectivity for timing was strongly correlated with selectivity for identity. Taken together with the previous research, these results suggest that when reward features are correlated, OFC tends to “pack” them into unitary constructs, whereas when they are independent, OFC tends to “crack” them into separate constructs. Furthermore, we found that when both reward timing and flavor were changed, reward-responsive OFC neurons showed unique activity patterns preceding and during the omission of an expected reward. Interestingly, this OFC activity is similar and slightly preceded the ventral tegmental area dopamine (VTA DA) activity observed in a previous study (Takahashi et al., 2023), consistent with the role of OFC in providing predictive information to VTA DA neurons. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Modeling Impaired Insight After Drug Use in Rodents.

Author

Panayi, Marios Chris and Schoenbaum, Geoffrey

Abstract

Impaired insight in substance use disorder has been argued to reflect a global deficit in using cognitive models to mentally simulate possible future outcomes. The process of mentally simulating outcomes allows us to understand our beliefs about their causes, that is, to have insight and thereby avoid potentially negative outcomes. However, work in humans cannot address whether impaired insight and its neural/neurochemical sequalae are present prior to the development of a substance use disorder, a consequence of substance use, or a combination of both. This is because baseline measurements prior to drug use are not possible in humans. However, if these changes can be directly caused by drug use, then in animal models, a history of drug use should cause impairments in behavioral tasks designed to assess such inferences. Focusing on cocaine use, here we will review several lines of research from our laboratory that have tested this question using learning-theory tasks designed to isolate insight. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Evolving schema representations in orbitofrontal ensembles during learning

Author

Zhou, Jingfeng, Jia, Chunying, Montesinos-Cartagena, Marlian, Gardner, Matthew P. H., Zong, Wenhui, and Schoenbaum, Geoffrey

Subjects
Learning -- Physiological aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

How do we learn about what to learn about? Specifically, how do the neural elements in our brain generalize what has been learned in one situation to recognize the common structure of--and speed learning in--other, similar situations? We know this happens because we become better at solving new problems--learning and deploying schemas.sup.1-5--through experience. However, we have little insight into this process. Here we show that using prior knowledge to facilitate learning is accompanied by the evolution of a neural schema in the orbitofrontal cortex. Single units were recorded from rats deploying a schema to learn a succession of odour-sequence problems. With learning, orbitofrontal cortex ensembles converged onto a low-dimensional neural code across both problems and subjects; this neural code represented the common structure of the problems and its evolution accelerated across their learning. These results demonstrate the formation and use of a schema in a prefrontal brain region to support a complex cognitive operation. Our results not only reveal a role for the orbitofrontal cortex in learning but also have implications for using ensemble analyses to tap into complex cognitive functions. Rats learning to solve a succession of odour-sequence problems developed an orbitofrontal cortical representation that reflected the structure--or schema--common across problems., Author(s): Jingfeng Zhou [sup.1] , Chunying Jia [sup.2] , Marlian Montesinos-Cartagena [sup.1] , Matthew P. H. Gardner [sup.1] , Wenhui Zong [sup.1] , Geoffrey Schoenbaum [sup.1] Author Affiliations: (1) Intramural [...]

Published
2021
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16. Different Effects of Peer Sex on Operant Responding for Social Interaction and Striatal Dopamine Activity.

Author

Chow, Jonathan J., Pitts, Kayla M., Schoenbaum, Ansel, Costa, Kauê M., Schoenbaum, Geoffrey, and Shaham, Yavin

Abstract

When rats are given discrete choices between social interactions with a peer and opioid or psychostimulant drugs, they choose social interaction, even after extensive drug self-administration experience. Studies show that like drug and nondrug food reinforcers, social interaction is an operant reinforcer and induces dopamine release. However, these studies were conducted with same-sex peers. We examined if peer sex influences operant social interaction and the role of estrous cycle and striatal dopamine in sameversus opposite-sex social interaction. We trained male and female rats (n = 13 responders/12 peers) to lever-press (fixed-ratio 1 [FR1] schedule) for 15 s access to a same- or opposite-sex peer for 16 d (8 d/sex) while tracking females' estrous cycle. Next, we transfected GRAB-DA2m and implanted optic fibers into nucleus accumbens (NAc) core and dorsomedial striatum (DMS). We then retrained the rats for 15 s social interaction (FR1 schedule) for 16 d (8 d/sex) and recorded striatal dopamine during operant responding for a peer for 8 d (4 d/sex). Finally, we assessed economic demand by manipulating FR requirements for a peer (10 d/sex). In male, but not female rats, operant responding was higher for the opposite-sex peer. Female's estrous cycle fluctuations had no effect on operant social interaction. Striatal dopamine signals for operant social interaction were dependent on the peer's sex and striatal region (NAc core vs DMS). Results indicate that estrous cycle fluctuations did not influence operant social interaction and that NAc core and DMS dopamine activity reflect sex-dependent features of volitional social interaction. [ABSTRACT FROM AUTHOR]

Published
2024
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30. Contributors

Author

Balleine, Bernard W., primary, Bertran-Gonzalez, Jesus, additional, Bhui, Rahul, additional, Botvinick, Matthew M., additional, Carelli, Regina M., additional, Chang, Luke J., additional, Collins, Anne G.E., additional, Corbit, Laura H., additional, Coutureau, Etienne, additional, Cushman, Fiery A., additional, de Wit, Sanne, additional, Dickinson, Anthony, additional, FeldmanHall, Oriel, additional, Furlong, Teri M., additional, Gershman, Samuel J., additional, Hartley, Catherine A., additional, Kool, Wouter, additional, Laurent, Vincent, additional, Liljeholm, Mimi, additional, Ludvig, Elliot A., additional, Miller, Kevin J., additional, Morris, Richard W., additional, Moschak, Travis M., additional, Niv, Yael, additional, Parkes, Shauna L., additional, Pérez, Omar D., additional, Pezzulo, Giovanni, additional, Raab, Hillary A., additional, David Redish, A., additional, Schmidt, Brandy, additional, Schoenbaum, Geoffrey, additional, Schuck, Nicolas W., additional, Sharpe, Melissa J., additional, Shenhav, Amitai, additional, Solway, Alec, additional, West, Elizabeth A., additional, Wikenheiser, Andrew M., additional, and Wilson, Robert, additional

Published
2018
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37. Dopamine

Author

Costa, Kauê Machado, primary and Schoenbaum, Geoffrey, additional

Published
2022
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42. Prior Cocaine Exposure Disrupts Extinction of Fear Conditioning

Author

Gugsa, Nishan, Schoenbaum, Geoffrey, and Burke, Kathryn A.

Abstract

Psychostimulant exposure has been shown to cause molecular and cellular changes in prefrontal cortex. It has been hypothesized that these drug-induced changes might affect the operation of prefrontal-limbic circuits, disrupting their normal role in controlling behavior and thereby leading to compulsive drug-seeking. To test this hypothesis, we tested cocaine-treated rats in a fear conditioning, inflation, and extinction task, known to depend on medial prefrontal cortex and amygdala. Cocaine-treated rats conditioned and inflated similar to saline controls but displayed slower extinction learning. These results support the hypothesis that control processes in the medial prefrontal cortex are impaired by cocaine exposure.

Published
2006

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