Controlling morpho-electrophysiological variability of neurons with detailed biophysical models

Arnaudon, Alexis; Reva, Maria; Zbili, Mickaël; Markram, Henry; Geit, Werner Van; Kanari, Lida

doi:10.1101/2023.04.06.535923

Cited by 3 publications

(1 citation statement)

References 55 publications

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“… 43 To further understand and possibly improve the generalizability of canonical e-models, one would need to study the link between morphological properties and electrical features of the e-models in more depth. 54 …”

Section: Discussionmentioning

confidence: 99%

A universal workflow for creation, validation, and generalization of detailed neuronal models

Reva,

Rössert,

Arnaudon

et al. 2023

Patterns

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Section: Discussionmentioning

confidence: 99%

A universal workflow for creation, validation, and generalization of detailed neuronal models

Reva,

Rössert,

Arnaudon

et al. 2023

Patterns

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Morphological variability may limit single-cell specificity to electric field stimulation

Trotter

Pariz

Hutt

et al. 2023

Preprint

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Non-invasive brain stimulation techniques are widely used for manipulating the behaviour of neuronal circuits and the excitability of the neurons therein. While the usage of these techniques is widely studied at the meso- and macroscopic scales, less is known about the specificity of such approaches at the level of individual cells. Here we use models based on the morphologies of real pyramidal and parvalbumin neurons from mouse primary visual cortex created by the Allen Institute for Brain Science to explore the variability and evoked response susceptibility of different morphologies to uniform electric fields. We devised a range of metrics quantifying various aspects of cellular morphology, ranging from whole cell attributes to net compartment length, branching, diameter to orientation. In supporting layer- and cell-type specific responses, none of these physical traits passed statistical significance tests. While electric fields can modulate somatic, dendritic and axonal compartments reliably and subtype-specific responses could be observed, the specificity of such stimuli was blurred by the variability in cellular morphology. These null results suggest that morphology alone may not account for the reported subtype specificity of brain stimulation paradigms, and question the extent to which such techniques may be used to probe and control neural circuitry.

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Higher-Order Interactions in Neuronal Function: From Genes to Ionic Currents in Biophysical Models

Reva,

Arnaudon,

Zbili

et al. 2024

Preprint

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Neuronal firing patterns are the consequence of precise variations in neuronal membrane potential, which are themselves shaped by multiple ionic currents. In this study, we use biophysical models, statistical methods, and information theory to explore the interaction between these ionic currents and neuron electrophysiological phenotype. We created numerous electrical models with diverse firing patterns using Monte Carlo Markov Chain methods. By analyzing these models, we identified intricate relationships between model parameters and electrical features. Our findings show that neuronal features are often influenced by multiple ionic currents sharing synergistic relationships. We also applied our methods to single-cell RNAseq data, discovering gene expression modules specific to certain interneuron types. This research sheds light on the complex links between biophysical parameters and neuronal phenotypes.

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Controlling morpho-electrophysiological variability of neurons with detailed biophysical models

Cited by 3 publications

References 55 publications

A universal workflow for creation, validation, and generalization of detailed neuronal models

A universal workflow for creation, validation, and generalization of detailed neuronal models

Morphological variability may limit single-cell specificity to electric field stimulation

Higher-Order Interactions in Neuronal Function: From Genes to Ionic Currents in Biophysical Models

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