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

Reimann, Michael; Bolaños-Puchet, Sirio; Courcol, Jean-Denis; Santander, Daniela Egas; Arnaudon, Alexis; Coste, B.; Delemontex, Thomas; Devresse, Adrien; Dictus, Hugo; Dietz, A.; Ecker, András; Favreau, Cyrille; Ficarelli, Gianluca; Gevaert, Mike; Hernando, Juan; Herttuainen, Joni; Isbister, James B.; Kanari, Lida; Keller, Daniel; King, James G.; Kumbhar, Pramod; Lapere, Samuel; Lazovskis, Jānis; Lu, Huanxiang; Ninin, Nicolas; Pereira, F.L.; Planas, Judit; Pokorny, Christoph; Riquelme, Juan Luis; Romani, Armando; Shi, Ying; Smith, Jason P.; Sood, Vishal; Srivastava, Mohit; Geit, Werner Van; Vanherpe, Liesbeth; Wolf, M.; Levi, Ran; Hess, Kathryn; Schürmann, Felix; Müller, Eilif; Ramaswamy, Srikanth; Markram, Henry

doi:10.1101/2022.08.11.503144

Cited by 14 publications

(67 citation statements)

References 104 publications

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“…In terms of spatial distribution of assembly neurons, the early assemblies appear more “patchy” (small distinguishable clusters), and by visual inspection can be mapped back to the locations of VPM fibers corresponding to the stimuli that activated them (Figures 2B and 3C top). Moreover, their layer profile mimics that of VPM fiber innervation (Meyer et al, 2010; Reimann et al, 2022b) (Supplementary Figure S4A), indicating that these assemblies may be determined by direct thalamic innervation. On the other hand, the late assembly neurons are more evenly distributed, and cover the entire surface of the simulated circuit, even beyond the range of VPM fiber centers, and are found mostly in deeper layers of the cortex.…”

Section: Resultsmentioning

confidence: 91%

“…The most recent version of the detailed, large-scale cortical microcircuit model of Markram et al (2015) was used for the in silico experiments in this study. Updates on its anatomy, e.g., atlas-based cell densities are described in Reimann et al (2022b). Updates on the physiology of single cell models and multi-vesicular release of synapses are described in Reva et al (2022) and Barros-Zulaica et al (2019).…”

Section: Network Simulationsmentioning

confidence: 99%

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Cortical cell assemblies and their underlying connectivity: anin silicostudy

Ecker

Santander

Bolaños-Puchet

et al. 2023

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Recent developments in experimental techniques have enabled simultaneous recordings from thousands of neurons, enabling the study of functional cell assemblies. However, determining the patterns of synaptic connectivity giving rise to assemblies remains challenging. To address this, we developed a complementary, simulation-based approach, using a detailed, large-scale cortical network model. Using a combination of established methods we detected functional cell assemblies from the stimulus-evoked spiking activity of 186,665 neurons. We studied how the structure of synaptic connectivity underlies assembly composition, quantifying the effects of thalamic innervation, recurrent connectivity, and the spatial arrangement of synapses on dendrites. We determined that these features reduce up to 30%, 22%, and 10% of the uncertainty of a neuron belonging to an assembly. The detected assemblies were activated in a stimulus-specific sequence and were grouped based on their position in the sequence. We found that the different groups were affected to different degrees by the structural features we considered. Additionally, connectivity was more predictive of assembly membership if its direction aligned with the temporal order of assembly activation, if it originated from strongly interconnected populations, and if synapses clustered on dendritic branches. In summary, reversing Hebb's postulate, we showed how cells that are wired together, fire together, quantifying how connectivity patterns interact to shape the emergence of assemblies. This includes a qualitative aspect of connectivity: not just the amount, but also the local structure matters; from the subcellular level in the form of dendritic clustering to the presence of specific network motifs. This connectivity-based characterization of cell assemblies creates an opportunity to study plasticity at the assembly level, and beyond strictly pairwise interactions.

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Section: Resultsmentioning

confidence: 91%

Section: Network Simulationsmentioning

confidence: 99%

Cortical cell assemblies and their underlying connectivity: anin silicostudy

Ecker

Santander

Bolaños-Puchet

et al. 2023

Preprint

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“…A total of 1, 015 reconstructed rat morphologies ([Reimann et al, 2022, Ramaswamy et al, 2015], expanded dataset from Markram et al [2015]) have been curated and repaired for cut plane missing data, following the procedure outlined in Markram et al [2015]. In that study a cloning strategy was applied by successive application of rescaling operations and jitter of section lengths and bifurcations angles.…”

Section: Methodsmentioning

confidence: 99%

“…For this purpose we used a total of 1, 015 reconstructed and manually corrected morphologies of SSCx young rat cortex for the generalization routine (see Methods). The population of morphologies was artificially increased to 141, 733 by a cloning procedure on the reconstructions [Reimann et al, 2022]. Given their m-type, morphologies were then attributed to one of the possible morpho-electro combinations [Markram et al, 2015[Markram et al, , 2004] (see Methods), yielding 366,926 models, of which 233,941 passed generalization.…”

Section: Generalization Of Electrical Modelsmentioning

confidence: 99%

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

Reva

Rössert

Arnaudon

et al. 2022

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Detailed single neuron modeling is widely used to study neuronal functions. While cellular and functional diversity across the mammalian cortex is vast, most of the available computational tools are dedicated to the reproduction of a small set of specific features characteristic of a single neuron. Here, we present a generalized automated workflow for the creation of robust electrical models and illustrate its performance by building cell models for the rat somatosensory cortex (SSCx). Each model is based on a 3D morphological reconstruction and a set of ionic mechanisms specific to the cell type. We use an evolutionary algorithm to optimize passive and active ionic parameters to match the electrophysiological features extracted from whole-cell patch-clamp recordings. To shed light on which parameters are constrained by experimental data and which could be degenerate, we perform a parameter sensitivity analysis. We also validate the optimized models against additional experimental stimuli and assess their generalizability on a population of morphologies with the same morphological type. With this workflow, we generate SSCx neuronal models producing the variability of neuronal responses. Due to its versatility, our workflow can be used to build robust biophysical models of any neuronal type.

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“…Our in silico neuromodulation model was implemented in a digital microcircuit extracted from a large-scale model covering the entirety of the non-barrel primary somatosensory cortex of the juvenile rat (Reimann et al, 2022). The microcircuit is 26 times smaller than the whole S1 region and comprises 163528 cells arranged in 7 cortical columns stacked horizontally.…”

Section: Microcircuitmentioning

confidence: 99%

Neuromodulatory organization in the developing rat somatosensory cortex

Colangelo

Muñoz

Antonietti

et al. 2022

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The vast majority of cortical synapses are found in the neuropil which is implicated in multiple and diverse functions underlying brain computation. Unraveling the organizing principles of the cortical neuropil requires an intricate characterization of synaptic connections established by excitatory and inhibitory axon terminals, of intrinsic and extrinsic origin and from ascending projections that govern the function of cortical microcircuits through the release of neuromodulators either through point-to-point chemical synapses or diffuse volume transmission (VT). Even though neuromodulatory release has been studied for almost a century it is still not clear if one modality prevails upon the other. The hindlimb representation of the somatosensory cortex (HLS1) of two-week old Wistar rats has served as a model system to dissect the microcircuitry of neurons and their synaptic connections. In the present study, we quantified the fiber length per cortical volume and the density of varicosities for cholinergic, catecholaminergic and serotonergic neuromodulatory systems in the cortical neuropil using immunocytochemical staining and stereological techniques. Acquired data were integrated into a novel computational framework to reconcile the specific modalities and predict the effects of neuromodulatory release in shaping neocortical network activity. We predict that acetylcholine (ACh), dopamine (DA), serotonin (5-HT) release desynchronizes cortical activity by inhibiting slow oscillations (delta range), and that 5-HT triggers faster oscillations (theta). Moreover, we found that high levels (>40%) of neuromodulatory VT are sufficient to induce network desynchronization, but also that combining volume release with synaptic inputs leads to more robust and stable effects, meaning that lower levels of VT are needed to achieve the same outcome (10%).

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

Cited by 14 publications

References 104 publications

Cortical cell assemblies and their underlying connectivity: anin silicostudy

Cortical cell assemblies and their underlying connectivity: anin silicostudy

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

Neuromodulatory organization in the developing rat somatosensory cortex

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