Institute of Science and Technology Austria, Klosterneuburg, Austria.
Centro Atómico Bariloche, Instituto Balseiro, Comisión Nacional de Energía Atómica (CNEA) and Universidad Nacional de Cuyo (UNCUYO), Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), San Carlos de Bariloche, Argentina.
Hippocampus. 2020 Apr;30(4):302-313. doi: 10.1002/hipo.23144. Epub 2019 Jul 24.
Nearby grid cells have been observed to express a remarkable degree of long-range order, which is often idealized as extending potentially to infinity. Yet their strict periodic firing and ensemble coherence are theoretically possible only in flat environments, much unlike the burrows which rodents usually live in. Are the symmetrical, coherent grid maps inferred in the lab relevant to chart their way in their natural habitat? We consider spheres as simple models of curved environments and waiting for the appropriate experiments to be performed, we use our adaptation model to predict what grid maps would emerge in a network with the same type of recurrent connections, which on the plane produce coherence among the units. We find that on the sphere such connections distort the maps that single grid units would express on their own, and aggregate them into clusters. When remapping to a different spherical environment, units in each cluster maintain only partial coherence, similar to what is observed in disordered materials, such as spin glasses.
附近的网格细胞已经被观察到具有显著的长程有序性,这种有序性通常被理想化地延伸到无限远。然而,它们严格的周期性放电和整体相干性在理论上只可能存在于平坦的环境中,而这与啮齿动物通常生活的洞穴有很大的不同。在实验室中推断出的对称、相干的网格图与它们在自然栖息地中的导航方式有关吗?我们将球体视为弯曲环境的简单模型,并且在等待适当的实验来进行的同时,我们使用我们的适应模型来预测在具有相同类型的递归连接的网络中会出现什么样的网格图,在平面上这些连接会产生单元之间的相干性。我们发现,在球体上,这种连接会扭曲单个网格单元自身会表达的地图,并将它们聚集在一起形成簇。当重新映射到不同的球形环境时,每个簇中的单元只保持部分相干性,类似于在无序材料(如自旋玻璃)中观察到的情况。
