Modeling sequential cognitive states via population level cortical dynamics
M Virginia Bolelli, Luca Greco, Dario Prandi
TLDR
This paper models sequential cognitive states using a novel neural-field system that approximates heteroclinic dynamics for brain activity patterns.
Key contributions
- Introduces a mathematical model for cyclic and sequential brain activity patterns.
- Addresses limitations of existing neural-field models in supporting heteroclinic cycles.
- Uses Universal Approximation Theorem to create an Amari-type neural-field system.
- Demonstrates the model's ability to reproduce cognitive state transitions in meditation.
Why it matters
This research offers a novel mathematical framework to understand how the brain transitions between different cognitive states. By bridging heteroclinic dynamics with neural-field theory, it provides a more biologically plausible model for sequential brain activity. This could advance our understanding of complex cognitive processes like attention.
Original Abstract
In this work, we present a mathematical model for cyclic and sequential patterns of brain activity, combining heteroclinic dynamics with discrete neural-field models. We first show that spatial-discrete neural-field equations with biologically realistic equilibria cannot support heteroclinic cycles. On the other hand, heterocline dynamics often arise in Lotka-Volterra-type systems, but these equations do not directly correspond to neuronal processes. To address this, we use a version of the Universal Approximation Theorem to approximate any target dynamics by a neural network interpretable as a high-dimensional Amari-type neural-field system. When the target dynamics contains a heteroclinic cycle, the approximating vector field generates a periodic trajectory that closely follows the heteroclinic connection. As a case study, we consider the cognitive processes underlying focused-attention meditation. We show how the model reproduces sequential transitions among cognitive states and we conclude providing a neural interpretation of the approximating dynamics.
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