Kaho Tsumura scite author profile

Flexible adaptation to changing environments is a representative executive control function implicated in the frontoparietal network that requires appropriate extraction of goal-relevant information through perception of the external environment. It remains unclear, however, how the flexibility is achieved under situations where goal-relevant information is uncertain. To address this issue, the current study examined neural mechanisms for task switching in which task-relevant information involved perceptual uncertainty. Twenty-eight human participants of both sexes alternated behavioral tasks in which they judged motion direction or color of visually presented colored dot stimuli that moved randomly. Task switching was associated with frontoparietal regions in the left hemisphere, and perception of ambiguous stimuli involved contralateral homologous frontoparietal regions. On the other hand, in stimulus-modality-dependent occipitotemporal regions, task coding information was increased during task switching. Effective connectivity analysis revealed that the frontal regions signaled toward the modality-dependent occipitotemporal regions when a relevant stimulus was more ambiguous, whereas the occipitotemporal regions signaled toward the frontal regions when the stimulus was more distinctive. These results suggest that complementary prefrontal mechanisms in the left and right hemispheres help to achieve a behavioral goal when the external environment involves perceptual uncertainty.

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Reversible fronto-occipitotemporal signaling complements task encoding and switching under ambiguous cues

Tsumura

Kosugi

Hattori

et al. 2020

Preprint

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Flexible adaptation to changing environments is one of the representative executive control functions, and requires appropriate extraction of environmental information to achieve a behavioral goal. It still remains unclear however, how the behavioral flexibility is guided under situations where the relevant behavior is ambiguous. Using functional brain mapping of machine-learning decoders and directional functional connectivity, we show that brain-wide reversible neural signaling underpins behavioral flexibility in ambiguously changing environments. When relevant behavior is cued ambiguously during behavioral shifting, neural coding of the behavior is attenuated in distributed cortical regions, but top-down signals from the prefrontal cortex complements the coding. On the other hand, when shifting to the alternative behavior is cued more explicitly, modality-specialized occipitotemporal regions implement distinct neural coding about the relevant behavior, and bottom-up signals from the occipitotemporal region to the prefrontal cortex supplements the behavioral shift. These results suggest that our adaptation to an ever-changing world is orchestrated by the alternation of top-down and bottom-up signaling in the fronto-occipitotemporal circuit depending on the availability of environmental evidences.Significance statementHow does the brain work when appropriate behavior is unclear? We found that when proper behavior was cued ambiguously, the prefrontal cortex signaled toward occipitotemporal regions. Functional brain mapping based on deep neural network revealed that neural coding of appropriate task was diminished in the occipitotemporal regions, which was complemented by the prefrontal signal. When the proper behavior was cued unambiguously, the occipitotemporal regions signaled the prefrontal cortex, which increased efficiency of the flexibility. Our results suggest that dynamic reversal of prefrontal-occipitotemporal signaling optimizes the behavioral flexibility depending on the perceptual ambiguity of the external world.

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Reversible Fronto-occipitotemporal Signaling Complements Task Encoding and Switching under Ambiguous Cues

Tsumura

Kosugi

Hattori

et al. 2021

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Adaptation to changing environments involves the appropriate extraction of environmental information to achieve a behavioral goal. It remains unclear how behavioral flexibility is guided under situations where the relevant behavior is ambiguous. Using functional brain mapping of machine learning decoders and directional functional connectivity, we show that brain-wide reversible neural signaling underpins task encoding and behavioral flexibility in ambiguously changing environments. When relevant behavior is cued ambiguously during behavioral shifting, neural coding is attenuated in distributed cortical regions, but top-down signals from the prefrontal cortex complement the coding. When behavioral shifting is cued more explicitly, modality-specialized occipitotemporal regions implement distinct neural coding about relevant behavior, and bottom-up signals from the occipitotemporal region to the prefrontal cortex supplement the behavioral shift. These results suggest that our adaptation to an ever-changing world is orchestrated by the alternation of top-down and bottom-up signaling in the fronto-occipitotemporal circuit depending on the availability of environmental information.

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Visual perceptual training reconfigures post-task resting-state functional connectivity with a feature-representation region

et al. 2018

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The neural mechanisms underlying visual perceptual learning (VPL) have typically been studied by examining changes in task-related brain activation after training. However, the relationship between post-task “offline” processes and VPL remains unclear. The present study examined this question by obtaining resting-state functional magnetic resonance imaging (fMRI) scans of human brains before and after a task-fMRI session involving visual perceptual training. During the task-fMRI session, participants performed a motion coherence discrimination task in which they judged the direction of moving dots with a coherence level that varied between trials (20, 40, and 80%). We found that stimulus-induced activation increased with motion coherence in the middle temporal cortex (MT+), a feature-specific region representing visual motion. On the other hand, stimulus-induced activation decreased with motion coherence in the dorsal anterior cingulate cortex (dACC) and bilateral insula, regions involved in decision making under perceptual ambiguity. Moreover, by comparing pre-task and post-task rest periods, we revealed that resting-state functional connectivity (rs-FC) with the MT+ was significantly increased after training in widespread cortical regions including the bilateral sensorimotor and temporal cortices. In contrast, rs-FC with the MT+ was significantly decreased in subcortical regions including the thalamus and putamen. Importantly, the training-induced change in rs-FC was observed only with the MT+, but not with the dACC or insula. Thus, our findings suggest that perceptual training induces plastic changes in offline functional connectivity specifically in brain regions representing the trained visual feature, emphasising the distinct roles of feature-representation regions and decision-related regions in VPL.

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Executive control by fronto-parietal activity explains counterintuitive decision behavior in complex value-based decision-making

et al. 2022

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Kaho Tsumura

Cross-Hemispheric Complementary Prefrontal Mechanisms during Task Switching under Perceptual Uncertainty

Reversible fronto-occipitotemporal signaling complements task encoding and switching under ambiguous cues

Reversible Fronto-occipitotemporal Signaling Complements Task Encoding and Switching under Ambiguous Cues

Visual perceptual training reconfigures post-task resting-state functional connectivity with a feature-representation region

Executive control by fronto-parietal activity explains counterintuitive decision behavior in complex value-based decision-making

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