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随着视觉工作记忆负荷增加,前额叶、海马体和颞下回之间相互作用的动态调整。

Dynamic adjustments in prefrontal, hippocampal, and inferior temporal interactions with increasing visual working memory load.

作者信息

Rissman Jesse, Gazzaley Adam, D'Esposito Mark

机构信息

Henry H. Wheeler, Jr. Brain Imaging Center, Department of Psychology, University of California-Berkeley, Berkeley, CA 94720, USA.

出版信息

Cereb Cortex. 2008 Jul;18(7):1618-29. doi: 10.1093/cercor/bhm195. Epub 2007 Nov 13.

DOI:10.1093/cercor/bhm195
PMID:17999985
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2905315/
Abstract

The maintenance of visual stimuli across a delay interval in working memory tasks is thought to involve reverberant neural communication between the prefrontal cortex and posterior visual association areas. Recent studies suggest that the hippocampus might also contribute to this retention process, presumably via reciprocal interactions with visual regions. To characterize the nature of these interactions, we performed functional connectivity analysis on an event-related functional magnetic resonance imaging data set in which participants performed a delayed face recognition task. As the number of faces that participants were required to remember was parametrically increased, the right inferior frontal gyrus (IFG) showed a linearly decreasing degree of functional connectivity with the fusiform face area (FFA) during the delay period. In contrast, the hippocampus linearly increased its delay period connectivity with both the FFA and the IFG as the mnemonic load increased. Moreover, the degree to which participants' FFA showed a load-dependent increase in its connectivity with the hippocampus predicted the degree to which its connectivity with the IFG decreased with load. Thus, these neural circuits may dynamically trade off to accommodate the particular mnemonic demands of the task, with IFG-FFA interactions mediating maintenance at lower loads and hippocampal interactions supporting retention at higher loads.

摘要

在工作记忆任务中,跨越延迟间隔维持视觉刺激被认为涉及前额叶皮层与后部视觉联合区域之间的回响神经通讯。最近的研究表明,海马体可能也有助于这一保持过程,大概是通过与视觉区域的相互作用。为了描述这些相互作用的性质,我们对一个事件相关功能磁共振成像数据集进行了功能连接分析,在该数据集中参与者执行了一个延迟面孔识别任务。随着要求参与者记住的面孔数量按参数增加,在延迟期,右侧额下回(IFG)与梭状面孔区(FFA)的功能连接程度呈线性下降。相反,随着记忆负荷增加,海马体与FFA和IFG的延迟期连接均呈线性增加。此外,参与者FFA与海马体连接的负荷依赖性增加程度预测了其与IFG连接随负荷下降的程度。因此,这些神经回路可能会动态权衡以适应任务的特定记忆需求,IFG-FFA相互作用在较低负荷下介导维持,而海马体相互作用在较高负荷下支持保持。

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