Clique topology reveals intrinsic geometric structure in neural correlations

Authors

Chad Giusti, University of PennsylvaniaFollow
Eva Pastalkova, Howard Hughes Medical Institute, Ashburn, VA
Carina Curto, University of Nebraska-LincolnFollow
Vladimir Itskov, Pennsylvania State University - Main CampusFollow

Date of this Version

2015

Citation

Clique topology reveals intrinsic geometric structure in neural correlations, Chad Giusti, Eva Pastalkova, Carina Curto, and Vladimir Itskov. PNAS. published 20 October 2015, 10.1073/pnas.1506407112

Comments

PNAS open access option.

Abstract

Detecting meaningful structure in neural activity and connectivity data is challenging in the presence of hidden nonlinearities, where traditional eigenvalue-based methods may be misleading. We introduce a novel approach to matrix analysis, called clique topology, that extracts features of the data invariant under nonlinear monotone transformations. These features can be used to detect both random and geometric structure, and depend only on the relative ordering of matrix entries. We then analyzed the activity of pyramidal neurons in rat hippocampus, recorded while the animal was exploring a 2D environment, and confirmed that our method is able to detect geometric organization using only the intrinsic pattern of neural correlations. Remarkably, we found similar results during nonspatial behaviors such as wheel running and rapid eye movement (REM) sleep. This suggests that the geometric structure of correlations is shaped by the underlying hippocampal circuits and is not merely a consequence of position coding. We propose that clique topology is a powerful new tool for matrix analysis in biological settings, where the relationship of observed quantities to more meaningful variables is often nonlinear and unknown.