Neuronal Responses in Posterior Parietal Cortex during Learning of Implied Serial Order

Muñoz, Fernando Miralles; Jensen, Greg; Kennedy, Benjamin C.; Alkan, Yelda; Terrace, H. S.; Ferrera, Vincent P.

doi:10.1101/689133

Cited by 3 publications

(5 citation statements)

References 75 publications

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“…We also find GMD in the parietal cortex, vmPFC and dlPFC to partially mediate age effects on positive feedback learning. The parietal cortex has been implicated in mapping the ordinal relationship among cues, a highly relevant feature when learning the relative rank order of task cues (Munoz et al, 2020). The vmPFC's relevance for feedback learning is also supported by work tying mPFC and mOFC to adaptive decision making and subjective value encoding (Rushworth et al, 2011) for positive (Kringelbach, 2005) and negative outcomes (Tom et al, 2007).…”

Section: Discussionmentioning

confidence: 99%

Cortical grey matter mediates increases in model-based control and learning from positive feedback from adolescence to adulthood

Scholz

Waltmann

Herzog

et al. 2022

Preprint

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Adolescents undergo maturation in cognition and brain structure. Model-based (MB) control is known to increase from childhood to young adulthood, which is mediated by cognitive abilities. Here, we asked two questions unaddressed in previous developmental studies: Firstly, what are the brain structural correlates of age-related increases in MB control? Secondly, how are age-related increases in MB control from adolescence to adulthood influenced by motivational context? A developmental sample (n=103, age: 12-42) completed structural MRI and an established task to capture MB control. The task was modified with respect to outcome valence by including (1) reward and punishment blocks to manipulate the motivational context and (2) an additional choice test to assess learning from positive vs. negative feedback. After replicating that an age-dependent increase in MB control is mediated by cognitive abilities, we demonstrate first-time evidence that grey matter density (GMD) in the parietal cortex mediates the increase of MB control with age. While motivational context did not relate to age-related changes in MB control, learning from positive feedback improved with age. Meanwhile, negative feedback learning showed no age effects. We present a first report that an age-related increase in learning from positive feedback was mediated by reduced GMD in the parietal, medial and dorsolateral prefrontal cortex. Our findings indicate that efficient brain maturation, as putatively reflected in lower GMD, in distinct and partially overlapping brain regions is a key developmental step towards age-related increases in planning and value-based choice.

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Section: Discussionmentioning

confidence: 99%

Cortical grey matter mediates increases in model-based control and learning from positive feedback from adolescence to adulthood

Scholz

Waltmann

Herzog

et al. 2022

Preprint

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show abstract

“…Despite the long history of TI as a cognitive task, investigation of its neural basis in the brain is comparatively recent [57,[90][91][92][93][94]. Prior work implies that an approach seeking to identify biologically accurate neural implementations would benefit from two criteria:…”

Section: A Neural Approach To Timentioning

confidence: 99%

“…Neural recordings in living subjects performing TI indicate that single neurons in the brain can encode variables relevant to TI, including symbolic distance [91,92]. It remains unclear what collective neural process or activity pattern implements the comparison operation-akin to a '>' operator-that generalizes transitivity to novel combinations of items.…”

Section: A Simple Neural Solution To Delay Timentioning

confidence: 99%

Emergent neural dynamics and geometry for generalization in a transitive inference task

Kay,

Biderman,

Khajeh

et al. 2024

PLoS Comput Biol

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Relational cognition—the ability to infer relationships that generalize to novel combinations of objects—is fundamental to human and animal intelligence. Despite this importance, it remains unclear how relational cognition is implemented in the brain due in part to a lack of hypotheses and predictions at the levels of collective neural activity and behavior. Here we discovered, analyzed, and experimentally tested neural networks (NNs) that perform transitive inference (TI), a classic relational task (if A > B and B > C, then A > C). We found NNs that (i) generalized perfectly, despite lacking overt transitive structure prior to training, (ii) generalized when the task required working memory (WM), a capacity thought to be essential to inference in the brain, (iii) emergently expressed behaviors long observed in living subjects, in addition to a novel order-dependent behavior, and (iv) expressed different task solutions yielding alternative behavioral and neural predictions. Further, in a large-scale experiment, we found that human subjects performing WM-based TI showed behavior inconsistent with a class of NNs that characteristically expressed an intuitive task solution. These findings provide neural insights into a classical relational ability, with wider implications for how the brain realizes relational cognition.

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“…Despite the long history of TI as a cognitive task, investigation of its neural basis in the brain is relatively recent [52, 61, 62, 63, 64, 65]. Prior work implies that an approach seeking to identify biologically accurate neural implementations would benefit from three criteria:…”

Section: A Neural Approach To Transitive Inferencementioning

confidence: 99%

“…Neural recordings in living subjects performing TI indicate that single neurons in the brain can encode variables relevant to TI, including symbolic distance [62, 63]. It remains unclear what collective neural process or activity pattern implements the comparison operation – akin to a ‘>‘ operator – that generalizes transitivity to novel combinations of items (test cases).…”

Section: A Simple Dynamic and Geometry Implementing Transitive Compar...mentioning

confidence: 99%

Emergent neural dynamics and geometry for generalization in a transitive inference task

Kay

Wei

Khajeh

et al. 2022

Preprint

Self Cite

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The ability to make inferences using abstract rules and relations has long been understood to be a hallmark of human intelligence, as evidenced in logic, mathematics, and language. Intriguingly, modern work in animal cognition has established that this ability is evolutionarily widespread, indicating an ancient and possibly foundational role in natural intelligence. Despite this importance, it remains an open question how inference using abstract rules is implemented in the brain - possibly due to a lack of competing hypotheses at the level of collective neural activity and of behavior. Here we report the generation and analysis of a collection of neural networks (NNs) that perform transitive inference (TI), a classical cognitive task that requires inference of a single abstract relation between novel combinations of inputs (if A > B and B > C, then A > C). We found that NNs generated using standard training methods (i) generalize fully (i.e. to all novel combinations of inputs), (ii) generalize when inference requires working memory (WM), a capacity thought to be essential for inference in living subjects, (iii) express multiple emergent behaviors long documented in humans and animals, in addition to novel behaviors not previously studied, and (iv) adopt different solutions that yield alternative predictions for both behavior and collective neural activity. Further, a subset of NNs expressed a "subtractive" solution that was characterized in neural activity space by a simple dynamical pattern (an oscillation) and geometric arrangement (ordered collinearity). Together, these findings show how collective neural activity can accomplish generalization according to an abstract rule, and provide a series of testable hypotheses not previously established in the study of TI. More broadly, these findings suggest new ways to understand how neural systems realize abstract rules and relations.

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Neuronal Responses in Posterior Parietal Cortex during Learning of Implied Serial Order

Cited by 3 publications

References 75 publications

Cortical grey matter mediates increases in model-based control and learning from positive feedback from adolescence to adulthood

Cortical grey matter mediates increases in model-based control and learning from positive feedback from adolescence to adulthood

Emergent neural dynamics and geometry for generalization in a transitive inference task

Emergent neural dynamics and geometry for generalization in a transitive inference task

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