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Heterogeneous and higher-order cortical connectivity undergirds efficient, robust, and reliable neural codes

Daniela Egas Santander, Christoph Pokorny, András Ecker, Jānis Lazovskis, Matteo Santoro, Jason P. Smith, Kathryn Hess, Ran Levi, Michael Reimann

2024iScience11 citationsDOIOpen Access PDF

Abstract

We hypothesized that the heterogeneous architecture of biological neural networks provides a substrate to regulate the well-known tradeoff between robustness and efficiency, thereby allowing different subpopulations of the same network to optimize for different objectives. To distinguish between subpopulations, we developed a metric based on the mathematical theory of simplicial complexes that captures the complexity of their connectivity by contrasting its higher-order structure to a random control and confirmed its relevance in several openly available connectomes. Using a biologically detailed cortical model and an electron microscopic dataset, we showed that subpopulations with low simplicial complexity exhibit efficient activity. Conversely, subpopulations of high simplicial complexity play a supporting role in boosting the reliability of the network as a whole, softening the robustness-efficiency tradeoff. Crucially, we found that both types of subpopulations can and do coexist within a single connectome in biological neural networks, due to the heterogeneity of their connectivity.

Topics & Concepts

Order (exchange)Computer scienceComputational biologyBiologyEconomicsFinanceNeural dynamics and brain functionFunctional Brain Connectivity StudiesAdvanced Memory and Neural Computing
Heterogeneous and higher-order cortical connectivity undergirds efficient, robust, and reliable neural codes | Litcius