Your search keyword '"Kanari, L."' showing total 18 results

1. MorphOMICs : a new algorithm to unravel region- and sex-dependent microglia morphological plasticity in health and disease

Author

Colombo, G., Cubero, R. J. A., Venturino, A., Kanari, L., Schulz, R., Scolamiero, Martina, Agerberg, Jens, Mathys, H., Tsai, L. -H, Chachólski, Wojciech, Hess, K., Siegert, S., Colombo, G., Cubero, R. J. A., Venturino, A., Kanari, L., Schulz, R., Scolamiero, Martina, Agerberg, Jens, Mathys, H., Tsai, L. -H, Chachólski, Wojciech, Hess, K., and Siegert, S.

Abstract

QC 20240415

Published

2023

2. Resolving the morpho-functional responses of locally-constrained retinal microglia with morphOMICs

Author

Cubero, R. J., Colombo, G., Venturino, A., Schulz, R., Maes, M., Gharagozlou, S., Scolamiero, Martina, Agerberg, Jens, Kanari, L., Hess, K., Chachólski, Wojciech, Siegert, S., Cubero, R. J., Colombo, G., Venturino, A., Schulz, R., Maes, M., Gharagozlou, S., Scolamiero, Martina, Agerberg, Jens, Kanari, L., Hess, K., Chachólski, Wojciech, and Siegert, S.

Abstract

QC 20240415

Published

2023

3. Supplementary material for poster 'Input representation and processing in a computational model of the rat primary somatosensory cortex'

Author

Bolaños-Puchet, S., Ecker, A., Pokorny, C., Isbister, J. B., Sood, V., Gevaert, M., Kumbhar, P., Arnaudon, A., Kanari, L., Van Geit, W., Markram, H., Courcol, J-D., Reimann, M. W., and Ramaswamy, S.

Subjects

neuroscience, sense organs, simulation

Abstract

Supplementary material for poster "Input representation and processing in a computational model of the rat primary somatosensory cortex" (P385.05) presented at SfN Global Connectome 2021. The files are organized per panel in the poster, with contents as follows: Panel C: three tables with connectivity statistics per pathway for each type of connectivity, and a Jupyter notebook to generate the figure Panel D: additional figure showing results of calibration of miniature PSCs for spontaneous synaptic release Panel E: full spike rasters and histograms per cell class for each parameter combination of the calcium-depolarization scan Panel F: spike rasters and histograms for increasing numbers of stimulated fibers with and without mid-range projections; for 24 stimulated fibers, full-scale spike raster and histogram for single column, spike rasters for all columns, movies of spiking activity as seen from above, movies of spiking activity as seen from above per layer, movies of spiking activity in a single column with audio (mapping cortical depth to frequency and number of spikes to amplitude) Panel G: full-scale versions of figures 2 and 3, plus additional spike rasters from in vivo and in silico data Panel H: full spike raster showing pattern presentations, This work was supported by funding to the Blue Brain Project, a research center of the École polytechnique fédérale de Lausanne (EPFL), from the Swiss government's ETH Board of the Swiss Federal Institutes of Technology.

Published

2021

4. Topological classification of microglia topological classification of microglia

Author

Colombo, G., Venturino, A., Schulz, R., Kanari, L., Hess, K., and Siegert, S.

5. Computational Generation of Long-range Axonal Morphologies.

Author

Berchet A, Petkantchin R, Markram H, and Kanari L

Subjects

Animals, Brain physiology, Brain cytology, Humans, Neurons physiology, Neurons cytology, Axons physiology, Computer Simulation trends, Models, Neurological, Algorithms

Abstract

Long-range axons are fundamental to brain connectivity and functional organization, enabling communication between different brain regions. Recent advances in experimental techniques have yielded a substantial number of whole-brain axonal reconstructions. While previous computational generative models of neurons have predominantly focused on dendrites, generating realistic axonal morphologies is more challenging due to their distinct targeting. In this study, we present a novel algorithm for axon synthesis that combines algebraic topology with the Steiner tree algorithm, an extension of the minimum spanning tree, to generate both the local and long-range compartments of axons. We demonstrate that our computationally generated axons closely replicate experimental data in terms of their morphological properties. This approach enables the generation of biologically accurate long-range axons that span large distances and connect multiple brain regions, advancing the digital reconstruction of the brain. Ultimately, our approach opens up new possibilities for large-scale in-silico simulations, advancing research into brain function and disorders., Competing Interests: Declarations. Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published

2025

6. Of mice and men: Dendritic architecture differentiates human from mice neuronal networks.

Author

Kanari L, Shi Y, Arnaudon A, Barros-Zulaica N, Benavides-Piccione R, Coggan JS, DeFelipe J, Hess K, Mansvelder HD, Mertens EJ, Meystre J, de Campos Perin R, Pezzoli M, Daniel RT, Stoop R, Segev I, Markram H, and de Kock CPJ

Abstract

The organizational principles that distinguish the human brain from other species have been a long-standing enigma in neuroscience. Focusing on the uniquely evolved human cortical layers 2 and 3, we computationally reconstruct the cortical architecture for mice and humans. We show that human pyramidal cells form highly complex networks, demonstrated by the increased number and simplex dimension compared to mice. This is surprising because human pyramidal cells are much sparser in the cortex. We show that the number and size of neurons fail to account for this increased network complexity, suggesting that another morphological property is a key determinant of network connectivity. Topological comparison of dendritic structure reveals much higher perisomatic (basal and oblique) branching density in human pyramidal cells. Using topological tools we quantitatively show that this neuronal structural property directly impacts network complexity, including the formation of a rich subnetwork structure. We conclude that greater dendritic complexity, a defining attribute of human L2 and 3 neurons, may provide the human cortex with enhanced computational capacity and cognitive flexibility.

Published

2024

7. Community-based reconstruction and simulation of a full-scale model of the rat hippocampus CA1 region.

Author

Romani A, Antonietti A, Bella D, Budd J, Giacalone E, Kurban K, Sáray S, Abdellah M, Arnaudon A, Boci E, Colangelo C, Courcol JD, Delemontex T, Ecker A, Falck J, Favreau C, Gevaert M, Hernando JB, Herttuainen J, Ivaska G, Kanari L, Kaufmann AK, King JG, Kumbhar P, Lange S, Lu H, Lupascu CA, Migliore R, Petitjean F, Planas J, Rai P, Ramaswamy S, Reimann MW, Riquelme JL, Román Guerrero N, Shi Y, Sood V, Sy MF, Van Geit W, Vanherpe L, Freund TF, Mercer A, Muller E, Schürmann F, Thomson AM, Migliore M, Káli S, and Markram H

Subjects

Animals, Rats, Theta Rhythm physiology, Synapses physiology, Acetylcholine metabolism, CA1 Region, Hippocampal physiology, Computer Simulation, Models, Neurological

Abstract

The CA1 region of the hippocampus is one of the most studied regions of the rodent brain, thought to play an important role in cognitive functions such as memory and spatial navigation. Despite a wealth of experimental data on its structure and function, it has been challenging to integrate information obtained from diverse experimental approaches. To address this challenge, we present a community-based, full-scale in silico model of the rat CA1 that integrates a broad range of experimental data, from synapse to network, including the reconstruction of its principal afferents, the Schaffer collaterals, and a model of the effects that acetylcholine has on the system. We tested and validated each model component and the final network model, and made input data, assumptions, and strategies explicit and transparent. The unique flexibility of the model allows scientists to potentially address a range of scientific questions. In this article, we describe the methods used to set up simulations to reproduce in vitro and in vivo experiments. Among several applications in the article, we focus on theta rhythm, a prominent hippocampal oscillation associated with various behavioral correlates and use our computer model to reproduce experimental findings. Finally, we make data, code, and model available through the hippocampushub.eu portal, which also provides an extensive set of analyses of the model and a user-friendly interface to facilitate adoption and usage. This community-based model represents a valuable tool for integrating diverse experimental data and provides a foundation for further research into the complex workings of the hippocampal CA1 region., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Romani et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

8. Controlling morpho-electrophysiological variability of neurons with detailed biophysical models.

Author

Arnaudon A, Reva M, Zbili M, Markram H, Van Geit W, and Kanari L

Abstract

Variability, which is known to be a universal feature among biological units such as neuronal cells, holds significant importance, as, for example, it enables a robust encoding of a high volume of information in neuronal circuits and prevents hypersynchronizations. While most computational studies on electrophysiological variability in neuronal circuits were done with single-compartment neuron models, we instead focus on the variability of detailed biophysical models of neuron multi-compartmental morphologies. We leverage a Markov chain Monte Carlo method to generate populations of electrical models reproducing the variability of experimental recordings while being compatible with a set of morphologies to faithfully represent specifi morpho-electrical type. We demonstrate our approach on layer 5 pyramidal cells and study the morpho-electrical variability and in particular, find that morphological variability alone is insufficient to reproduce electrical variability. Overall, this approach provides a strong statistical basis to create detailed models of neurons with controlled variability., Competing Interests: The authors declare no competing interests., (© 2023 The Author(s).)

Published

2023

9. Strong and reliable synaptic communication between pyramidal neurons in adult human cerebral cortex.

Author

Hunt S, Leibner Y, Mertens EJ, Barros-Zulaica N, Kanari L, Heistek TS, Karnani MM, Aardse R, Wilbers R, Heyer DB, Goriounova NA, Verhoog MB, Testa-Silva G, Obermayer J, Versluis T, Benavides-Piccione R, de Witt-Hamer P, Idema S, Noske DP, Baayen JC, Lein ES, DeFelipe J, Markram H, Mansvelder HD, Schürmann F, Segev I, and de Kock CPJ

Subjects

Rats, Adult, Animals, Humans, Mice, Rats, Wistar, Pyramidal Cells physiology, Synaptic Transmission physiology, Synapses physiology, Receptors, N-Methyl-D-Aspartate physiology, Neocortex

Abstract

Synaptic transmission constitutes the primary mode of communication between neurons. It is extensively studied in rodent but not human neocortex. We characterized synaptic transmission between pyramidal neurons in layers 2 and 3 using neurosurgically resected human middle temporal gyrus (MTG, Brodmann area 21), which is part of the distributed language circuitry. We find that local connectivity is comparable with mouse layer 2/3 connections in the anatomical homologue (temporal association area), but synaptic connections in human are 3-fold stronger and more reliable (0% vs 25% failure rates, respectively). We developed a theoretical approach to quantify properties of spinous synapses showing that synaptic conductance and voltage change in human dendritic spines are 3-4-folds larger compared with mouse, leading to significant NMDA receptor activation in human unitary connections. This model prediction was validated experimentally by showing that NMDA receptor activation increases the amplitude and prolongs decay of unitary excitatory postsynaptic potentials in human but not in mouse connections. Since NMDA-dependent recurrent excitation facilitates persistent activity (supporting working memory), our data uncovers cortical microcircuit properties in human that may contribute to language processing in MTG., (© The Author(s) 2022. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permission@oup.com.)

Published

2023

10. A tool for mapping microglial morphology, morphOMICs, reveals brain-region and sex-dependent phenotypes.

Author

Colombo G, Cubero RJA, Kanari L, Venturino A, Schulz R, Scolamiero M, Agerberg J, Mathys H, Tsai LH, Chachólski W, Hess K, and Siegert S

Subjects

Animals, Brain, Disease Models, Animal, Female, Male, Mice, Phenotype, Ketamine, Microglia

Abstract

Environmental cues influence the highly dynamic morphology of microglia. Strategies to characterize these changes usually involve user-selected morphometric features, which preclude the identification of a spectrum of context-dependent morphological phenotypes. Here we develop MorphOMICs, a topological data analysis approach, which enables semiautomatic mapping of microglial morphology into an atlas of cue-dependent phenotypes and overcomes feature-selection biases and biological variability. We extract spatially heterogeneous and sexually dimorphic morphological phenotypes for seven adult mouse brain regions. This sex-specific phenotype declines with maturation but increases over the disease trajectories in two neurodegeneration mouse models, with females showing a faster morphological shift in affected brain regions. Remarkably, microglia morphologies reflect an adaptation upon repeated exposure to ketamine anesthesia and do not recover to control morphologies. Finally, we demonstrate that both long primary processes and short terminal processes provide distinct insights to morphological phenotypes. MorphOMICs opens a new perspective to characterize microglial morphology., (© 2022. The Author(s).)

Published

2022

11. Computational synthesis of cortical dendritic morphologies.

Author

Kanari L, Dictus H, Chalimourda A, Arnaudon A, Van Geit W, Coste B, Shillcock J, Hess K, and Markram H

Subjects

Algorithms, Brain, Neurons, Connectome, Dendrites physiology

Abstract

Neuronal morphologies provide the foundation for the electrical behavior of neurons, the connectomes they form, and the dynamical properties of the brain. Comprehensive neuron models are essential for defining cell types, discerning their functional roles, and investigating brain-disease-related dendritic alterations. However, a lack of understanding of the principles underlying neuron morphologies has hindered attempts to computationally synthesize morphologies for decades. We introduce a synthesis algorithm based on a topological descriptor of neurons, which enables the rapid digital reconstruction of entire brain regions from few reference cells. This topology-guided synthesis generates dendrites that are statistically similar to biological reconstructions in terms of morpho-electrical and connectivity properties and offers a significant opportunity to investigate the links between neuronal morphology and brain function across different spatiotemporal scales. Synthesized cortical networks based on structurally altered dendrites associated with diverse brain pathologies revealed principles linking branching properties to the structure of large-scale networks., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

12. Digital Reconstruction of the Neuro-Glia-Vascular Architecture.

Author

Zisis E, Keller D, Kanari L, Arnaudon A, Gevaert M, Delemontex T, Coste B, Foni A, Abdellah M, Calì C, Hess K, Magistretti PJ, Schürmann F, and Markram H

Subjects

Animals, Neurons physiology, Rats, Signal Transduction, Somatosensory Cortex, Astrocytes physiology, Neuroglia

Abstract

Astrocytes connect the vasculature to neurons mediating the supply of nutrients and biochemicals. They are involved in a growing number of physiological and pathophysiological processes that result from biophysical, physiological, and molecular interactions in this neuro-glia-vascular ensemble (NGV). The lack of a detailed cytoarchitecture severely restricts the understanding of how they support brain function. To address this problem, we used data from multiple sources to create a data-driven digital reconstruction of the NGV at micrometer anatomical resolution. We reconstructed 0.2 mm3 of the rat somatosensory cortex with 16 000 morphologically detailed neurons, 2500 protoplasmic astrocytes, and its microvasculature. The consistency of the reconstruction with a wide array of experimental measurements allows novel predictions of the NGV organization, allowing the anatomical reconstruction of overlapping astrocytic microdomains and the quantification of endfeet connecting each astrocyte to the vasculature, as well as the extent to which they cover the latter. Structural analysis showed that astrocytes optimize their positions to provide uniform vascular coverage for trophic support and signaling. However, this optimal organization rapidly declines as their density increases. The NGV digital reconstruction is a resource that will enable a better understanding of the anatomical principles and geometric constraints, which govern how astrocytes support brain function., (© The Author(s) 2021. Published by Oxford University Press.)

Published

2021

13. Objective Morphological Classification of Neocortical Pyramidal Cells.

Author

Kanari L, Ramaswamy S, Shi Y, Morand S, Meystre J, Perin R, Abdellah M, Wang Y, Hess K, and Markram H

Subjects

Animals, Imaging, Three-Dimensional, Lysine analogs & derivatives, Pattern Recognition, Automated, Rats, Supervised Machine Learning, Neocortex cytology, Pyramidal Cells cytology, Somatosensory Cortex cytology

Abstract

A consensus on the number of morphologically different types of pyramidal cells (PCs) in the neocortex has not yet been reached, despite over a century of anatomical studies, due to the lack of agreement on the subjective classifications of neuron types, which is based on expert analyses of neuronal morphologies. Even for neurons that are visually distinguishable, there is no common ground to consistently define morphological types. The objective classification of PCs can be achieved with methods from algebraic topology, and the dendritic arborization is sufficient for the reliable identification of distinct types of cortical PCs. Therefore, we objectively identify 17 types of PCs in the rat somatosensory cortex. In addition, we provide a solution to the challenging problem of whether 2 similar neurons belong to different types or to a continuum of the same type. Our topological classification does not require expert input, is stable, and helps settle the long-standing debate on whether cell-types are discrete or continuous morphological variations of each other., (© The Author 2019. Published by Oxford University Press.)

Published

2019

14. A Topological Representation of Branching Neuronal Morphologies.

Author

Kanari L, Dłotko P, Scolamiero M, Levi R, Shillcock J, Hess K, and Markram H

Subjects

Computational Biology methods, Data Analysis, Decision Trees, Models, Neurological, Neurons physiology

Abstract

Many biological systems consist of branching structures that exhibit a wide variety of shapes. Our understanding of their systematic roles is hampered from the start by the lack of a fundamental means of standardizing the description of complex branching patterns, such as those of neuronal trees. To solve this problem, we have invented the Topological Morphology Descriptor (TMD), a method for encoding the spatial structure of any tree as a "barcode", a unique topological signature. As opposed to traditional morphometrics, the TMD couples the topology of the branches with their spatial extents by tracking their topological evolution in 3-dimensional space. We prove that neuronal trees, as well as stochastically generated trees, can be accurately categorized based on their TMD profiles. The TMD retains sufficient global and local information to create an unbiased benchmark test for their categorization and is able to quantify and characterize the structural differences between distinct morphological groups. The use of this mathematically rigorous method will advance our understanding of the anatomy and diversity of branching morphologies.

Published

2018

15. Comprehensive Morpho-Electrotonic Analysis Shows 2 Distinct Classes of L2 and L3 Pyramidal Neurons in Human Temporal Cortex.

Author

Deitcher Y, Eyal G, Kanari L, Verhoog MB, Atenekeng Kahou GA, Mansvelder HD, de Kock CPJ, and Segev I

Subjects

Adult, Animals, Brain Neoplasms surgery, Cell Size, Epilepsy surgery, Humans, Imaging, Three-Dimensional methods, Mice, Middle Aged, Models, Statistical, Patch-Clamp Techniques, Principal Component Analysis, Signal Processing, Computer-Assisted, Species Specificity, Temporal Lobe surgery, Tissue Culture Techniques, Young Adult, Pyramidal Cells cytology, Pyramidal Cells physiology, Temporal Lobe cytology, Temporal Lobe physiology

Abstract

There have been few quantitative characterizations of the morphological, biophysical, and cable properties of neurons in the human neocortex. We employed feature-based statistical methods on a rare data set of 60 3D reconstructed pyramidal neurons from L2 and L3 in the human temporal cortex (HL2/L3 PCs) removed after brain surgery. Of these cells, 25 neurons were also characterized physiologically. Thirty-two morphological features were analyzed (e.g., dendritic surface area, 36 333 ± 18 157 μm2; number of basal trees, 5.55 ± 1.47; dendritic diameter, 0.76 ± 0.28 μm). Eighteen features showed a significant gradual increase with depth from the pia (e.g., dendritic length and soma radius). The other features showed weak or no correlation with depth (e.g., dendritic diameter). The basal dendritic terminals in HL2/L3 PCs are particularly elongated, enabling multiple nonlinear processing units in these dendrites. Unlike the morphological features, the active biophysical features (e.g., spike shapes and rates) and passive/cable features (e.g., somatic input resistance, 47.68 ± 15.26 MΩ, membrane time constant, 12.03 ± 1.79 ms, average dendritic cable length, 0.99 ± 0.24) were depth-independent. A novel descriptor for apical dendritic topology yielded 2 distinct classes, termed hereby as "slim-tufted" and "profuse-tufted" HL2/L3 PCs; the latter class tends to fire at higher rates. Thus, our morpho-electrotonic analysis shows 2 distinct classes of HL2/L3 PCs., (© The Author 2017. Published by Oxford University Press.)

Published

2017

16. Framework for efficient synthesis of spatially embedded morphologies.

Author

Vanherpe L, Kanari L, Atenekeng G, Palacios J, and Shillcock J

Abstract

Many problems in science and engineering require the ability to grow tubular or polymeric structures up to large volume fractions within a bounded region of three-dimensional space. Examples range from the construction of fibrous materials and biological cells such as neurons, to the creation of initial configurations for molecular simulations. A common feature of these problems is the need for the growing structures to wind throughout space without intersecting. At any time, the growth of a morphology depends on the current state of all the others, as well as the environment it is growing in, which makes the problem computationally intensive. Neuron synthesis has the additional constraint that the morphologies should reliably resemble biological cells, which possess nonlocal structural correlations, exhibit high packing fractions, and whose growth responds to anatomical boundaries in the synthesis volume. We present a spatial framework for simultaneous growth of an arbitrary number of nonintersecting morphologies that presents the growing structures with information on anisotropic and inhomogeneous properties of the space. The framework is computationally efficient because intersection detection is linear in the mass of growing elements up to high volume fractions and versatile because it provides functionality for environmental growth cues to be accessed by the growing morphologies. We demonstrate the framework by growing morphologies of various complexity.

Published

2016

17. Reconstruction and Simulation of Neocortical Microcircuitry.

Author

Markram H, Muller E, Ramaswamy S, Reimann MW, Abdellah M, Sanchez CA, Ailamaki A, Alonso-Nanclares L, Antille N, Arsever S, Kahou GA, Berger TK, Bilgili A, Buncic N, Chalimourda A, Chindemi G, Courcol JD, Delalondre F, Delattre V, Druckmann S, Dumusc R, Dynes J, Eilemann S, Gal E, Gevaert ME, Ghobril JP, Gidon A, Graham JW, Gupta A, Haenel V, Hay E, Heinis T, Hernando JB, Hines M, Kanari L, Keller D, Kenyon J, Khazen G, Kim Y, King JG, Kisvarday Z, Kumbhar P, Lasserre S, Le Bé JV, Magalhães BR, Merchán-Pérez A, Meystre J, Morrice BR, Muller J, Muñoz-Céspedes A, Muralidhar S, Muthurasa K, Nachbaur D, Newton TH, Nolte M, Ovcharenko A, Palacios J, Pastor L, Perin R, Ranjan R, Riachi I, Rodríguez JR, Riquelme JL, Rössert C, Sfyrakis K, Shi Y, Shillcock JC, Silberberg G, Silva R, Tauheed F, Telefont M, Toledo-Rodriguez M, Tränkler T, Van Geit W, Díaz JV, Walker R, Wang Y, Zaninetta SM, DeFelipe J, Hill SL, Segev I, and Schürmann F

Subjects

Algorithms, Animals, Hindlimb innervation, Male, Neocortex physiology, Nerve Net, Neurons physiology, Rats, Rats, Wistar, Somatosensory Cortex physiology, Computer Simulation, Models, Neurological, Neocortex cytology, Neurons classification, Neurons cytology, Somatosensory Cortex cytology

Abstract

We present a first-draft digital reconstruction of the microcircuitry of somatosensory cortex of juvenile rat. The reconstruction uses cellular and synaptic organizing principles to algorithmically reconstruct detailed anatomy and physiology from sparse experimental data. An objective anatomical method defines a neocortical volume of 0.29 ± 0.01 mm(3) containing ~31,000 neurons, and patch-clamp studies identify 55 layer-specific morphological and 207 morpho-electrical neuron subtypes. When digitally reconstructed neurons are positioned in the volume and synapse formation is restricted to biological bouton densities and numbers of synapses per connection, their overlapping arbors form ~8 million connections with ~37 million synapses. Simulations reproduce an array of in vitro and in vivo experiments without parameter tuning. Additionally, we find a spectrum of network states with a sharp transition from synchronous to asynchronous activity, modulated by physiological mechanisms. The spectrum of network states, dynamically reconfigured around this transition, supports diverse information processing strategies., Paperclip: VIDEO ABSTRACT., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

18. The neocortical microcircuit collaboration portal: a resource for rat somatosensory cortex.

Author

Ramaswamy S, Courcol JD, Abdellah M, Adaszewski SR, Antille N, Arsever S, Atenekeng G, Bilgili A, Brukau Y, Chalimourda A, Chindemi G, Delalondre F, Dumusc R, Eilemann S, Gevaert ME, Gleeson P, Graham JW, Hernando JB, Kanari L, Katkov Y, Keller D, King JG, Ranjan R, Reimann MW, Rössert C, Shi Y, Shillcock JC, Telefont M, Van Geit W, Diaz JV, Walker R, Wang Y, Zaninetta SM, DeFelipe J, Hill SL, Muller J, Segev I, Schürmann F, Muller EB, and Markram H

Subjects

Animals, Rats, Cooperative Behavior, Information Systems, Neocortex, Somatosensory Cortex

Published

2015