Santos-Pata, D., Amil, A. F., Raikov, I. G., Rennó-Costa, C., Mura, A., Soltesz, I., & Verschure, P. F.
The hippocampal formation displays a wide range of physiological responses to different spatial manipulations of the environment. However, very few attempts have been made to identify core computational principles underlying those hippocampal responses. Here, we capitalize on the observation that the entorhinal-hippocampal complex (EHC) forms a closed loop and projects inhibitory signals “countercurrent” to the trisynaptic pathway to build a self-supervised model that learns to reconstruct its own inputs by error backpropagation. The EHC is then abstracted as an autoencoder, with the hidden layers acting as an information bottleneck. With the inputs mimicking the firing activity of lateral and medial entorhinal cells, our model is shown to generate place cells and to respond to environmental manipulations as observed in rodent experiments. Altogether, we propose that the hippocampus builds conjunctive compressed representations of the environment by learning to reconstruct its own entorhinal inputs via gradient descent.
Santos-Pata, D., Amil, A. F., Raikov, I. G., Rennó-Costa, C., Mura, A., Soltesz, I., & Verschure, P. F. (2021). A computational model of self-supervised learning in the hippocampus. iScience, 102364. https://doi.org/10.1016/j.isci.2021.102364