The cognitive basis of intracranial self-stimulation of midbrain dopamine neurons

Millard, Samuel J.; Hoang, Ivy B; Greer, Zara; O'Connor, Shayna L; Wassum, Kate M.; James, Morgan H.; Barker, David J.; Sharpe, Melissa J

doi:10.1101/2022.08.11.503670

Cited by 5 publications

(5 citation statements)

References 69 publications

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“…Normally, rats will not learn about the novel auditory cues because no new information can be attributed them as there is no change in reward identity or magnitude (i.e., blocking) 70 . However, during one of the rewards, we stimulated VTA DA terminals in LH as a prediction error by delivering blue light into LH (1-sec; 20Hz, 473nm, 14-16mW) 41, 42, 72 , to examine whether we could facilitate learning about one of the auditory cues (“unblocked”) while the other cue would serve as a control is not learned about (“blocked”). As we and others have previously shown that light alone in eYFP controls does not unblock learning using these parameters 30, 41, 42, 71 , we opted for a within-subjects blocking design where all rats had ChR2 infused into VTA DA neurons which allowed us to compare responding to unblocked and blocked cues in each rat.…”

Section: Resultsmentioning

confidence: 99%

A novel hypothalamic-midbrain circuit for model-based learning

Hoang

Munier

Verghese

et al. 2023

Preprint

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Behavior is often dichotomized into model-free and model-based systems1, 2. Model-free behavior prioritizes associations that have high value, regardless of the specific consequence or circumstance. In contrast, model-based behavior involves considering all possible outcomes to produce behavior that best fits the current circumstance. We typically exhibit a mixture of these behaviors so we can trade-off efficiency and flexibility. However, substance use disorder shifts behavior more strongly towards model-free systems, which produces a difficulty abstaining from drug-seeking due to an inability to withhold making the model-free high-value response3–10. The lateral hypothalamus (LH) is implicated in substance use disorder11–17and we have demonstrated that this region is critical to Pavlovian cue-reward learning18, 19. However, it is unknown whether learning occurring in LH is model-free or model-based, where the necessary teaching signal comes from to facilitate learning in LH, and whether this is relevant for learning deficits that drive substance use disorder. Here, we reveal that learning occurring in the LH is model-based. Further, we confirm the existence of an understudied projection extending from dopamine neurons in the ventral tegmental area (VTA) to the LH and demonstrate that this input underlies model-based learning in LH. Finally, we examine the impact of methamphetamine self-administration on LH-dependent model-based processes. These experiments reveal that a history of methamphetamine administration enhances the model-based control that Pavlovian cues have over decision-making, which was accompanied by a bidirectional strengthening of the LH to VTA circuit. Together, this work reveals a novel bidirectional circuit that underlies model-based learning and is relevant to the behavioral and cognitive changes that arise with substance use disorders. This circuit represents a new addition to models of addiction, which focus on instrumental components of drug addiction and increases in model-free habits after drug exposure3–10.

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Section: Resultsmentioning

confidence: 99%

A novel hypothalamic-midbrain circuit for model-based learning

Hoang

Munier

Verghese

et al. 2023

Preprint

Self Cite

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“…Additional evidence suggests that stimulating the same neuronal population at different frequencies could influence different types of behavior. Recent research examined whether rats would press a lever to optogenetically self‐stimulate dopamine neurons in the ventral tegmental area (Millard et al., 2022). The findings indicate that rats pressed a lever for 50 Hz neuronal stimulation but not for 20 Hz stimulation, even though 50 Hz stimulation exceeds the physiological limits of the spiking capabilities of the neurons.…”

Section: Frequency Specificitymentioning

confidence: 99%

Theoretical Considerations for Optimizing the Use of Optogenetics with Complex Behavior

Glickman,

LaLumiere

2023

Current Protocols

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Optogenetic approaches have allowed researchers to address complex questions about behavior that were previously unanswerable. However, as optogenetic procedures involve a large parameter space across multiple dimensions, it is crucial to consider such parameters in conjunction with the behaviors under study. Here, we discuss strategies to optimize optogenetic approaches with complex behavior by identifying critical experimental design considerations, including frequency specificity, temporal precision, activitycontrolled optogenetics, stimulation pattern, and cell-type specificity. We highlight potential limitations or theoretical considerations to be made when manipulating each of these factors of optogenetic experiments. This overview emphasizes the importance of optimizing optogenetic study design to enhance the conclusions that can be drawn about the neuroscience of behavior.

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“…It is incontrovertible that VTA DA stimulation acts as a reinforcing signal for actions and states (e.g., Olds & Milner, 1954; Wise, 1978; Schultz et al, 1997). Animals readily self-stimulate for, and frequent places where, electrical or optogenetic activation of VTA DA neurons occurred, and disrupting this activity prevents learning or reduces established reward-seeking responses (e.g., Carter et al, 2022; Corbett & Wise, 1980; Crow, 1972; Ilango et al, 2014; Pascoli et al, 2015; Phillips & Fibiger, 1973; Millard et al, 2022; Witten et al, 2010). An intuitive interpretation of these findings is that VTA DA activity constitutes an appetitive event that is intrinsically rewarding.…”

Section: Optogenetic Stimulation Of Vta Da Transients Promotes Learni...mentioning

confidence: 99%

Rewarding Value or Prediction Error: Settling the debate over the role of dopamine in reward learning

Usypchuk¹,

Maes²,

Lozzi³

et al. 2022

Preprint

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The discovery that DA transients can be mapped onto the reward prediction errors in temporal difference models is a pinnacle achievement of neuroscience. Yet, there is abundant evidence that DA activity reinforces actions, suggesting it serves as an intrinsically rewarding event. These two possibilities are so conceptually intertwined that it is not surprising that they have been so far experimentally conflated. Here, using computational modeling, behavioural blocking and optogenetics, we show that stimulating VTA DA neurons promotes learning even when a natural reward and DA stimulation are held constant across the learning phases of blocking. These findings provide strong evidence in favour of the prediction error hypothesis rather than encoding the rewarding value of appetitive events.

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The cognitive basis of intracranial self-stimulation of midbrain dopamine neurons

Cited by 5 publications

References 69 publications

A novel hypothalamic-midbrain circuit for model-based learning

A novel hypothalamic-midbrain circuit for model-based learning

Theoretical Considerations for Optimizing the Use of Optogenetics with Complex Behavior

Rewarding Value or Prediction Error: Settling the debate over the role of dopamine in reward learning

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