Laboratory of Cognitive and Computational Neuroscience (UCM-UPM), Center for Biomedical Technology, 28223 Pozuelo de Alarcón, Madrid, Spain.
Faculty of Health Sciences, King Juan Carlos University, 28922 Alcorcón, Madrid, Spain.
J Neurosci. 2020 Mar 18;40(12):2510-2518. doi: 10.1523/JNEUROSCI.1982-19.2020. Epub 2020 Feb 7.
Memories for past experiences can range from vague recognition to full-blown recall of associated details. Electroencephalography has shown that recall signals unfold a few hundred milliseconds after simple recognition, but has only provided limited insights into the underlying brain networks. Functional magnetic resonance imaging (fMRI) has revealed a "core recollection network" (CRN) centered on posterior parietal and medial temporal lobe regions, but the temporal dynamics of these regions during retrieval remain largely unknown. Here we used Magnetoencephalography in a memory paradigm assessing correct rejection (CR) of lures, item recognition (IR) and associative recall (AR) in human participants of both sexes. We found that power decreases in the alpha frequency band (10-12 Hz) systematically track different mnemonic outcomes in both time and space: Over left posterior sensors, alpha power decreased in a stepwise fashion from 500 ms onward, first from CR to IR and then from IR to AR. When projecting alpha power into source space, the CRN known from fMRI studies emerged, including posterior parietal cortex (PPC) and hippocampus. While PPC showed a monotonic change across conditions, hippocampal effects were specific to recall. These region-specific effects were corroborated by a separate fMRI dataset. Importantly, alpha power time courses revealed a temporal dissociation between item and associative memory in hippocampus and PPC, with earlier AR effects in hippocampus. Our data thus link engagement of the CRN to the temporal dynamics of episodic memory and highlight the role of alpha rhythms in revealing when and where different types of memories are retrieved. Our ability to remember ranges from the vague feeling of familiarity to vivid recollection of associated details. Scientific understanding of episodic memory thus far relied upon separate lines of research focusing on either temporal (via electroencephalography) or spatial (via functional magnetic resonance imaging) dimensions. However, both techniques have limitations that have hindered understanding of when and where memories are retrieved. Capitalizing on the enhanced temporal and spatial resolution of magnetoencephalography, we show that changes in alpha power reveal both when and where different types of memory are retrieved. Having access to the temporal and spatial characteristics of successful retrieval provided new insights into the cross-regional dynamics in the hippocampus and parietal cortex.
记忆可以从对过去经历的模糊识别到对相关细节的完整回忆。脑电图研究表明,回忆信号在简单识别后几百毫秒展开,但仅提供了对潜在大脑网络的有限见解。功能磁共振成像 (fMRI) 揭示了一个以顶后和内侧颞叶区域为中心的“核心回忆网络”(CRN),但这些区域在检索过程中的时间动态在很大程度上仍然未知。在这里,我们在一个记忆范式中使用脑磁图 (MEG) 评估了男女参与者的正确拒绝(CR)、项目识别(IR)和联想回忆(AR)。我们发现,在 alpha 频带(10-12 Hz)中的功率下降系统地在时间和空间上跟踪不同的记忆结果:在左后传感器上,从 500 毫秒开始,alpha 功率逐渐下降,首先从 CR 到 IR,然后从 IR 到 AR。当将 alpha 功率投影到源空间时,从 fMRI 研究中已知的 CRN 出现了,包括顶后皮质 (PPC) 和海马体。虽然 PPC 在条件下显示出单调变化,但海马体的影响是特定于回忆的。这些区域特异性效应得到了另一个 fMRI 数据集的证实。重要的是,alpha 功率时间过程揭示了海马体和 PPC 中项目和联想记忆之间的时间分离,海马体中较早出现 AR 效应。因此,我们的数据将 CRN 的参与与情景记忆的时间动态联系起来,并强调 alpha 节律在揭示何时以及何地检索不同类型的记忆方面的作用。我们的记忆能力从模糊的熟悉感到生动的回忆相关细节不等。目前,对情景记忆的科学理解依赖于分别侧重于时间(通过脑电图)或空间(通过功能磁共振成像)维度的独立研究线。然而,这两种技术都有其局限性,这阻碍了对何时何地检索记忆的理解。利用脑磁图的增强时间和空间分辨率,我们表明 alpha 功率的变化揭示了不同类型的记忆何时以及何地被检索。能够访问成功检索的时间和空间特征为海马体和顶叶皮层的跨区域动态提供了新的见解。
