Abstract
The continuous integration of experimental data into coherent models of the brain is an increasing challenge of modern neuroscience. Such models provide a bridge between structure and activity, and identify the mechanisms giving rise to experimental observations. Nevertheless, structurally realistic network models of spiking neurons are necessarily underconstrained even if experimental data on brain connectivity are incorporated to the best of our knowledge. Guided by physiological observations, any model must therefore explore the parameter ranges within the uncertainty of the data. Based on simulation results alone, however, the mechanisms underlying stable and physiologically realistic activity often remain obscure. We here employ a mean-field reduction of the dynamics, which allows us to include activity constraints into the process of model construction. We shape the phase space of a multi-scale network model of the vision-related areas of macaque cortex by systematically refining its connectivity. Fundamental constraints on the activity, i.e., prohibiting quiescence and requiring global stability, prove sufficient to obtain realistic layer- and area-specific activity. Only small adaptations of the structure are required, showing that the network operates close to an instability. The procedure identifies components of the network critical to its collective dynamics and creates hypotheses for structural data and future experiments. The method can be applied to networks involving any neuron model with a known gain function.
Highlights
The neural wiring diagram, the connectome, is gradually being filled through classical techniques combined with innovative quantitative analyses [1, 2] and new technologies [3, 4]
The influence of its constituents on the dynamics is a central topic in systems neuroscience
We here investigate the critical role of specific structural links between neuronal populations for the global stability of cortex and elucidate the relation between anatomical structure and experimentally observed activity
Summary
The neural wiring diagram, the connectome, is gradually being filled through classical techniques combined with innovative quantitative analyses [1, 2] and new technologies [3, 4]. The connectivity between neurons is considered to shape resting-state and task-related collective activity [5, 6]. Clear relationships with activity are known analytically, e.g., a dynamic balance between excitatory and inhibitory inputs in inhibition-dominated random networks leads to an asynchronous and irregular state [7,8,9]. The impact of local network structure on spiketime correlations is known in some detail [14,15,16]. There is a one-toone mapping between correlations in neuronal network activity and effective connectivity, a measure that depends on the network structure and on its activity [17]. Despite advances in understanding simple networks, a complete picture of the relationship between structure and dynamics remains elusive
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