A connectome manipulation framework for the systematic and reproducible study of structure–function relationships through simulations

Pokorny, Christoph; Awile, Omar; Isbister, James B.; Kurban, Kerem; Wolf, Matthias; Reimann, Michael W.

doi:10.1101/2024.05.24.593860

2024

DOI: 10.1101/2024.05.24.593860

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A connectome manipulation framework for the systematic and reproducible study of structure–function relationships through simulations

Christoph Pokorny,

Omar Awile,

James B. Isbister

et al.

Abstract: Synaptic connectivity at the neuronal level is characterized by highly non-random features. Hypotheses about their role can be developed by correlating structural metrics to functional features. But to prove causation, manipulations of connectivity would have to be studied. However, the fine-grained scale at which non-random trends are expressed makes this approach challenging to pursue experimentally. Simulations of neuronal networks provide an alternative route to study arbitrarily complex manipulations in m… Show more

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Cited by 4 publications

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Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part I: Anatomy

Reimann

Bolaños-Puchet

Courcol

et al. 2022

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The function of the neocortex is fundamentally determined by its repeating microcircuit motif, but also by its rich, hierarchical, interregional structure with a highly specific laminar architecture. The last decade has seen the emergence of extensive new data sets on anatomy and connectivity at the whole brain scale, providing promising new directions for studies of cortical function that take into account the inseparability of whole-brain and microcircuit architectures. Here, we present a data-driven computational model of the anatomy of non-barrel primary somatosensory cortex of juvenile rat, which integrates whole-brain scale data while providing cellular and subcellular specificity. This multiscale integration was achieved by building the morphologically detailed model of cortical circuitry embedded within a volumetric, digital brain atlas. The model consists of 4.2 million morphologically detailed neurons belonging to 60 different morphological types, placed in the nonbarrel subregions of the Paxinos and Watson atlas. They are connected by 13.2 billion synapses determined by axo-dendritic overlap, comprising local connectivity and long-range connectivity defined by topographic mappings between subregions and laminar axonal projection profiles, both parameterized by whole brain data sets. Additionally, we incorporated core- and matrix-type thalamocortical projection systems, associated with sensory and higher-order extrinsic inputs, respectively. An analysis of the modeled synaptic connectivity revealed a highly nonrandom topology with substantial structural differences but also synergy between local and long-range connectivity. Long-range connections featured a more divergent structure with a comparatively small group of neurons serving as hubs to distribute excitation to far away locations. Taken together with analyses at different spatial granularities, these results support the notion that local and interregional connectivity exist on a spectrum of scales, rather than as separate and distinct networks, as is commonly assumed. Finally, we predicted how the emergence of primary sensory cortical maps is constrained by the anatomy of thalamo-cortical projections. A subvolume of the model comprising 211,712 neurons in the front limb, jaw, and dysgranular zone has been made freely and openly available to the community.

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Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part I: Anatomy

Reimann

Bolaños-Puchet

Courcol

et al. 2022

Preprint

Self Cite

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Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part II: Physiology and Experimentation

Isbister,

Ecker,

Pokorny

et al. 2023

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In recent years, large-scale computational models of the cortex have emerged as a powerful way to study the multi-scale mechanisms of neural processing. However, due to computational costs and difficulty of parameterization, detailed biophysical reconstructions have so far been restricted to small volumes of tissue, where the study of macro- and meso-scale interactions that are central to cortical function is not possible. We describe here, and in a companion paper, an approach to address the scaling challenges and provide a model of multiple interacting cortical regions at a subcellular level of detail. The model consists of 4.2 million morphologically detailed neurons in 8 sub-regions and connected with 13.2 billion synapses through local and long-range connectivity. Its anatomical aspects are described in the companion paper; here, we introduce physiological models of neuronal activity and synaptic transmission that integrate a large number of literature sources and were built using previously published algorithms. Biological neuronal diversity was captured in 208 morpho-electrical neuron types, five types of synaptic short-term dynamics, and pathway-specificity of synaptic parameters. A representation of synaptic input from cortical regions not present in the model was added and efficiently calibrated to reference firing rates. The model exhibits a spectrum of dynamical states differing in the degree to which they are internally versus externally driven. We characterized which parts of the spectrum are compatible with available experimental data on layer-specific delays and amplitudes of responses to simple stimuli, and found anin vivo-like regime at the edge of a transition from asynchronous to synchronous spontaneous activity. We developed a rich set of simulation tools to recreate a diverse set of laboratory experimentsin silico, providing further validation and demonstrating the utility of the model in a variety of paradigms. Finally, we found that the large spatial scale of the model, that incorporates multiple cortical regions, led to the emergence of multiple independent computational units interacting through long-range synaptic pathways. The model provides a framework for the continued integration of experimental findings, for challenging hypotheses and making testable predictions, and provides a foundation for further simulation-based studies of cortical processing and learning.

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

Egas Santander,

Pokorny,

Ecker

et al. 2024

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Neurons in a neural circuit have been demonstrated to have astonishing diversity in terms of numbers and targets of their synaptic connectivity and the statistics of their spiking activity. We hypothesize that this is the result of an underlying struggle between reliability, robustness and efficiency of the information represented by their spike trains. Specifically, certain architectures of connectivity foster highly uncorrelated and thus efficient activity, others foster the opposite trends, i.e., robust activity. Both coexists in a neural circuit, leading to the observed long-tailed and highly diverse distributions of connectivity and activity metrics, and allowing the robust subpopulations to promote the reliability of the network as a whole. To test the hypothesis and characterize these architectures, we analyzed several openly available connectomes and found that all of them contained groups of neurons with very different levels of complexity of their connectivity. Using co-registered functional data and simulations of a morphologically detailed network model, we found that low complexity groups were indeed characterized by efficient spiking activity and high complexity groups by reliable but inefficient activity. Moreover, for neurons in cortical input layers, the focus was increasing reliability; for output layers, it was increasing efficiency. To test the effect of the complex subpopulations on the reliability of the network as a whole, we manipulated the connectivity in the model to increase or decrease complexity and confirmed that it affected activity in the expected ways. Our results impact our understanding of the neural code, demonstrating that it is as diverse as neuronal connectivity and activity, and must be understood in the context of the efficiency/reliability struggle.

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A connectome manipulation framework for the systematic and reproducible study of structure–function relationships through simulations

Cited by 4 publications

References 54 publications

Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part I: Anatomy

Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part I: Anatomy

Modeling and Simulation of Neocortical Micro- and Mesocircuitry. Part II: Physiology and Experimentation

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

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