Inferring occluded projectile motion changes connectivity within a visuo-fronto-parietal network.

IF 2.7 3区 医学 Q1 ANATOMY & MORPHOLOGY Brain Structure & Function Pub Date : 2024-09-01 Epub Date: 2024-06-25 DOI:10.1007/s00429-024-02815-2
Gabrielle Aude Zbären, Manu Kapur, Sarah Nadine Meissner, Nicole Wenderoth
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Abstract

Anticipating the behaviour of moving objects in the physical environment is essential for a wide range of daily actions. This ability is thought to rely on mental simulations and has been shown to involve frontoparietal and early visual areas. Yet, the connectivity patterns between these regions during intuitive physical inference remain largely unknown. In this study, participants underwent fMRI while performing a task requiring them to infer the parabolic trajectory of an occluded ball falling under Newtonian physics, and a control task. Building on our previous research showing that when solving the physical inference task, early visual areas encode task-specific and perception-like information about the inferred trajectory, the present study aimed to (i) identify regions that are functionally coupled with early visual areas during the physical inference task, and (ii) investigate changes in effective connectivity within this network of regions. We found that early visual areas are functionally connected to a set of parietal and premotor regions when inferring occluded trajectories. Using dynamic causal modelling, we show that predicting occluded trajectories is associated with changes in effective connectivity within a parieto-premotor network, which may drive internally generated early visual activity in a top-down fashion. These findings offer new insights into the interaction between early visual and frontoparietal regions during physical inference, contributing to our understanding of the neural mechanisms underlying the ability to predict physical outcomes.

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推断被遮挡的射弹运动会改变视觉-前额-顶叶网络的连通性。
预测物理环境中移动物体的行为对于各种日常行动至关重要。这种能力被认为依赖于心理模拟,并已被证明涉及额顶区和早期视觉区。然而,在直觉物理推理过程中,这些区域之间的连接模式在很大程度上仍是未知的。在这项研究中,受试者在完成一项要求他们推断一个被遮挡的球在牛顿物理学原理下的抛物线轨迹的任务和一项控制任务时接受了 fMRI 检查。我们之前的研究表明,在完成物理推理任务时,早期视觉区域会编码有关推理轨迹的任务特异性和感知类信息,在此基础上,本研究旨在(i)识别在物理推理任务中与早期视觉区域功能耦合的区域,以及(ii)研究该区域网络内有效连接的变化。我们发现,在推断闭塞轨迹时,早期视觉区域与一组顶叶和前运动区域存在功能连接。通过动态因果建模,我们发现预测闭塞轨迹与顶叶-运动前区网络内有效连接的变化有关,这可能以自上而下的方式驱动内部产生的早期视觉活动。这些发现为我们提供了在物理推理过程中早期视觉和额叶区域之间相互作用的新见解,有助于我们理解预测物理结果能力的神经机制。
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来源期刊
Brain Structure & Function
Brain Structure & Function 医学-解剖学与形态学
CiteScore
6.00
自引率
6.50%
发文量
168
审稿时长
8 months
期刊介绍: Brain Structure & Function publishes research that provides insight into brain structure−function relationships. Studies published here integrate data spanning from molecular, cellular, developmental, and systems architecture to the neuroanatomy of behavior and cognitive functions. Manuscripts with focus on the spinal cord or the peripheral nervous system are not accepted for publication. Manuscripts with focus on diseases, animal models of diseases, or disease-related mechanisms are only considered for publication, if the findings provide novel insight into the organization and mechanisms of normal brain structure and function.
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