Learning Hippo: Multi-attractor Dynamics and Stability Effects in a Biologically Detailed CA3 Extension of Hopfield Networks

Abstract

We present a biologically detailed extension of the classical Hopfield/Marr auto-associative memory model for CA3, implementing ten populations (two asymmetric pyramidal subtypes, eight GABAergic interneuron classes), forty-seven compartments, multi-rule plasticity (recurrent Hebb, BCM anti-saturation, mossy-fiber short-term, endocannabinoid iLTD, burst-gated Hebb), and a bimodal cholinergic encoding/consolidation cycle. Evaluated on pattern completion across auto-associative, associative, and temporal regimes, and on a controlled inhibitory-proportion manipulation at N=256, the full architecture exhibits three qualitative signatures absent from a minimal Hopfield baseline: (i)~multi-attractor cross-seed behaviour at K=5 with biologically realistic inhibitory proportions, where two of five seeds converge to positive attractors with margin +0.10-0.22 (Cohen's d=0.71, one-sided p=0.08); (ii)~target-selective associative recall in paired (A, B) memory at K≥5, where the full model retrieves B from a partial cue of A while the minimal model echoes A (Pearson margin =+0.163 at K=5); (iii)~reduced cross-seed variance of the full model below the minimal baseline under clean upstream, with ratios 1.0-3.0. These three signatures are architecture-specific: they appear consistently across independent regimes and are absent from the minimal control.