Wolbers Thomas, Wiener Jan M, Mallot Hanspeter A, Büchel Christian
Department of Psychology, University of California Santa Barbara, Santa Barbara, California 93106, USA.
J Neurosci. 2007 Aug 29;27(35):9408-16. doi: 10.1523/JNEUROSCI.2146-07.2007.
Path integration, the ability to sense self-motion for keeping track of changes in orientation and position, constitutes a fundamental mechanism of spatial navigation and a keystone for the development of cognitive maps. Whereas animal path integration is predominantly supported by the head-direction, grid, and place cell systems, the neural foundations are not well understood in humans. Here we used functional magnetic resonance imaging and a virtual rendition of a triangle completion paradigm to test whether human path integration recruits a cortical system similar to that of rodents and nonhuman primates. Participants traveled along two legs of a triangle before pointing toward the starting location. In accordance with animal models, stronger right hippocampal activation predicted more accurate updating of the starting location on a trial-by-trial basis. Moreover, between-subjects fluctuations in response consistency were negatively correlated with bilateral hippocampal and medial prefrontal activation, and bilateral recruitment of the human motion complex (hMT+) covaried with individual path integration capability. Given that these effects were absent in a perceptual control task, the present study provides the first evidence that visual path integration is related to the dynamic interplay of self-motion processing in hMT+, higher-level spatial processes in the hippocampus, and spatial working memory in medial prefrontal cortex.
路径整合,即感知自身运动以追踪方向和位置变化的能力,是空间导航的一种基本机制,也是认知地图发展的关键要素。动物的路径整合主要由头部方向、网格和位置细胞系统支持,但其神经基础在人类中尚未得到充分理解。在此,我们使用功能磁共振成像和三角形完成范式的虚拟再现,来测试人类路径整合是否会激活与啮齿动物和非人类灵长类动物相似的皮质系统。参与者沿着三角形的两条边行进,然后指向起始位置。与动物模型一致,更强的右侧海马体激活预示着在逐个试次的基础上对起始位置更准确的更新。此外,受试者间反应一致性的波动与双侧海马体和内侧前额叶激活呈负相关,人类运动复合体(hMT+)的双侧激活与个体路径整合能力共同变化。鉴于这些效应在知觉控制任务中不存在,本研究首次证明视觉路径整合与hMT+中自我运动处理、海马体中高级空间过程以及内侧前额叶皮质中空间工作记忆的动态相互作用有关。