Your search keyword '"Kaiser, Marcus"' showing total 20 results

1. Predictability of intelligence and age from structural connectomes.

Author

Kopetzky SJ, Li Y, Kaiser M, and Butz-Ostendorf M

Subjects

Young Adult, Humans, Magnetic Resonance Imaging methods, Brain diagnostic imaging, Intelligence, Diffusion Tensor Imaging methods, Connectome methods

Abstract

In this study, structural images of 1048 healthy subjects from the Human Connectome Project Young Adult study and 94 from ADNI-3 study were processed by an in-house tractography pipeline and analyzed together with pre-processed data of the same subjects from braingraph.org. Whole brain structural connectome features were used to build a simple correlation-based regression machine learning model to predict intelligence and age of healthy subjects. Our results showed that different forms of intelligence as well as age are predictable to a certain degree from diffusion tensor imaging detecting anatomical fiber tracts in the living human brain. Though we did not identify significant differences in the prediction capability for the investigated features depending on the imaging feature extraction method, we did find that crystallized intelligence was consistently better predictable than fluid intelligence from structural connectivity data through all datasets. Our findings suggest a practical and scalable processing and analysis framework to explore broader research topics employing brain MR imaging., Competing Interests: SJK and YL were employed with Labvantage – Biomax GmbH and therefore will be affected by any commercial implications caused by this manuscript. This does not alter our adherence to PLOS ONE policies on sharing data and materials., (Copyright: © 2024 Kopetzky 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

2. Spatial organisation of the mesoscale connectome: A feature influencing synchrony and metastability of network dynamics.

Author

Mackay M, Huo S, and Kaiser M

Subjects

Magnetic Resonance Imaging methods, Nerve Net pathology, Brain, Connectome methods, Neocortex

Abstract

Significant research has investigated synchronisation in brain networks, but the bulk of this work has explored the contribution of brain networks at the macroscale. Here we explore the effects of changing network topology on functional dynamics in spatially constrained random networks representing mesoscale neocortex. We use the Kuramoto model to simulate network dynamics and explore synchronisation and critical dynamics of the system as a function of topology in randomly generated networks with a distance-related wiring probability and no preferential attachment term. We show networks which predominantly make short-distance connections smooth out the critical coupling point and show much greater metastability, resulting in a wider range of coupling strengths demonstrating critical dynamics and metastability. We show the emergence of cluster synchronisation in these geometrically-constrained networks with functional organisation occurring along structural connections that minimise the participation coefficient of the cluster. We show that these cohorts of internally synchronised nodes also behave en masse as weakly coupled nodes and show intra-cluster desynchronisation and resynchronisation events related to inter-cluster interaction. While cluster synchronisation appears crucial to healthy brain function, it may also be pathological if it leads to unbreakable local synchronisation which may happen at extreme topologies, with implications for epilepsy research, wider brain function and other domains such as social networks., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Mackay 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

2023

3. Functional Connectivity Change in Response to Stroke Is Comparable Across Species: From Mouse to Man.

Author

Hall GR, Kaiser M, and Farr TD

Subjects

Animals, Mice, Connectome, Stroke

Published

2021

4. Computational models and fundamental constraints can inform the design of synthetic connectomes: Comment on "What would a synthetic connectome look like?" by Ithai Rabinowitch.

Author

Kaiser M

Subjects

Computer Simulation, Models, Neurological, Neural Pathways, Connectome

Published

2020

5. Dynamic functional connectivity changes in dementia with Lewy bodies and Alzheimer's disease.

Author

Schumacher J, Peraza LR, Firbank M, Thomas AJ, Kaiser M, Gallagher P, O'Brien JT, Blamire AM, and Taylor JP

Subjects

Aged, Aged, 80 and over, Alzheimer Disease diagnostic imaging, Cluster Analysis, Female, Humans, Lewy Body Disease diagnostic imaging, Magnetic Resonance Imaging, Male, Nerve Net diagnostic imaging, Alzheimer Disease physiopathology, Connectome methods, Lewy Body Disease physiopathology, Nerve Net physiopathology

Abstract

We studied the dynamic functional connectivity profile of dementia with Lewy bodies (DLB) and Alzheimer's disease (AD) compared to controls, how it differs between the two dementia subtypes, and a possible relation between dynamic connectivity alterations and temporally transient clinical symptoms in DLB. Resting state fMRI data from 31 DLB, 29 AD, and 31 healthy control participants were analyzed using dual regression to determine between-network functional connectivity. Subsequently, we used a sliding window approach followed by k-means clustering and dynamic network analyses to study dynamic functional connectivity. Dynamic connectivity measures that showed significant group differences were tested for correlations with clinical symptom severity. Our results show that AD and DLB patients spent more time than controls in sparse connectivity configurations with absence of strong positive and negative connections and a relative isolation of motor networks from other networks. Additionally, DLB patients spent less time in a more strongly connected state and the variability of global brain network efficiency was reduced in DLB compared to controls. There were no significant correlations between dynamic connectivity measures and clinical symptom severity. An inability to switch out of states of low inter-network connectivity into more highly and specifically connected network configurations might be related to the presence of dementia in general as it was observed in both AD and DLB. In contrast, the loss of global efficiency variability in DLB might indicate the presence of an abnormally rigid brain network and the lack of economical dynamics, factors which could contribute to cognitive slowing and an inability to respond appropriately to situational demands., (Copyright © 2019 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2019

6. Mechanisms of Connectome Development.

Author

Kaiser M

Subjects

Humans, Brain physiology, Connectome, Neural Networks, Computer

Abstract

At the centenary of D'Arcy Thompson's seminal work 'On Growth and Form', pioneering the description of principles of morphological changes during development and evolution, recent experimental advances allow us to study change in anatomical brain networks. Here, we outline potential principles for connectome development. We will describe recent results on how spatial and temporal factors shape connectome development in health and disease. Understanding the developmental origins of brain diseases in individuals will be crucial for deciding on personalized treatment options. We argue that longitudinal studies, experimentally derived parameters for connection formation, and biologically realistic computational models are needed to better understand the link between brain network development, network structure, and network function., (Copyright © 2017 The Author. Published by Elsevier Ltd.. All rights reserved.)

Published

2017

7. Within brain area tractography suggests local modularity using high resolution connectomics.

Author

Taylor PN, Wang Y, and Kaiser M

Subjects

Adult, Brain diagnostic imaging, Female, Gray Matter physiology, Humans, Male, White Matter physiology, Brain physiology, Connectome, Diffusion Tensor Imaging

Abstract

Previous structural brain connectivity studies have mainly focussed on the macroscopic scale of around 1,000 or fewer brain areas (network nodes). However, it has recently been demonstrated that high resolution structural connectomes of around 50,000 nodes can be generated reproducibly. In this study, we infer high resolution brain connectivity matrices using diffusion imaging data from the Human Connectome Project. With such high resolution we are able to analyse networks within brain areas in a single subject. We show that the global network has a scale invariant topological organisation, which means there is a hierarchical organisation of the modular architecture. Specifically, modules within brain areas are spatially localised. We find that long range connections terminate between specific modules, whilst short range connections via highly curved association fibers terminate within modules. We suggest that spatial locations of white matter modules overlap with cytoarchitecturally distinct grey matter areas and may serve as the structural basis for function specialisation within brain areas. Future studies might elucidate how brain diseases change this modular architecture within brain areas.

Published

2017

8. Predicting Surgery Targets in Temporal Lobe Epilepsy through Structural Connectome Based Simulations.

Author

Hutchings F, Han CE, Keller SS, Weber B, Taylor PN, and Kaiser M

Subjects

Adult, Aged, Computer Simulation, Diffusion Tensor Imaging methods, Epilepsy, Temporal Lobe surgery, Female, Humans, Male, Middle Aged, Models, Anatomic, Models, Neurological, Monitoring, Intraoperative methods, Neurophysiological Monitoring methods, Preoperative Care methods, Treatment Outcome, Connectome methods, Epilepsy, Temporal Lobe pathology, Hippocampus pathology, Hippocampus surgery, Patient-Specific Modeling, Surgery, Computer-Assisted methods

Abstract

Temporal lobe epilepsy (TLE) is a prevalent neurological disorder resulting in disruptive seizures. In the case of drug resistant epilepsy resective surgery is often considered. This is a procedure hampered by unpredictable success rates, with many patients continuing to have seizures even after surgery. In this study we apply a computational model of epilepsy to patient specific structural connectivity derived from diffusion tensor imaging (DTI) of 22 individuals with left TLE and 39 healthy controls. We validate the model by examining patient-control differences in simulated seizure onset time and network location. We then investigate the potential of the model for surgery prediction by performing in silico surgical resections, removing nodes from patient networks and comparing seizure likelihood post-surgery to pre-surgery simulations. We find that, first, patients tend to transit from non-epileptic to epileptic states more often than controls in the model. Second, regions in the left hemisphere (particularly within temporal and subcortical regions) that are known to be involved in TLE are the most frequent starting points for seizures in patients in the model. In addition, our analysis also implicates regions in the contralateral and frontal locations which may play a role in seizure spreading or surgery resistance. Finally, the model predicts that patient-specific surgery (resection areas chosen on an individual, model-prompted, basis and not following a predefined procedure) may lead to better outcomes than the currently used routine clinical procedure. Taken together this work provides a first step towards patient specific computational modelling of epilepsy surgery in order to inform treatment strategies in individuals.

Published

2015

9. Divergent brain functional network alterations in dementia with Lewy bodies and Alzheimer's disease.

Author

Peraza LR, Taylor JP, and Kaiser M

Subjects

Aged, Aged, 80 and over, Brain blood supply, Cohort Studies, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Mental Status Schedule, Nerve Net blood supply, Oxygen blood, Statistics, Nonparametric, Alzheimer Disease pathology, Brain pathology, Connectome, Lewy Body Disease pathology, Nerve Net pathology

Abstract

The clinical phenotype of dementia with Lewy bodies (DLB) is different from Alzheimer's disease (AD), suggesting a divergence between these diseases in terms of brain network organization. To fully understand this, we studied functional networks from resting-state functional magnetic resonance imaging in cognitively matched DLB and AD patients. The DLB group demonstrated a generalized lower synchronization compared with the AD and healthy controls, and this was more severe for edges connecting distant brain regions. Global network measures were significantly different between DLB and AD. For instance, AD showed lower small-worldness than healthy controls, while DLB showed higher small-worldness (AD < controls < DLB), and this was also the case for global efficiency (DLB > controls > AD) and clustering coefficient (DLB < controls < AD). Differences were also found for nodal measures at brain regions associated with each disease. Finally, we found significant associations between network performance measures and global cognitive impairment and severity of cognitive fluctuations in DLB. These results show network divergences between DLB and AD which appear to reflect their neuropathological differences., (Copyright © 2015 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2015

10. Neuroanatomy: connectome connects fly and mammalian brain networks.

Author

Kaiser M

Subjects

Animals, Female, Male, Brain physiology, Connectome, Drosophila melanogaster physiology, Nerve Net

Abstract

A recent study shows that brain connectivity in Drosophila melanogaster follows a small-world, modular and rich-club organisation that facilitates information processing. This organisation shows a striking similarity with the mammalian brain., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

11. Structural connectivity changes in temporal lobe epilepsy: Spatial features contribute more than topological measures.

Author

Taylor PN, Han CE, Schoene-Bake JC, Weber B, and Kaiser M

Subjects

Adolescent, Adult, Aged, Female, Humans, Male, Middle Aged, Young Adult, Connectome methods, Epilepsy, Temporal Lobe pathology, Magnetic Resonance Imaging methods, Nerve Net pathology

Abstract

Background: Previous studies reported reduced volumes of many brain regions for temporal lobe epilepsy (TLE). It has also been suggested that there may be widespread changes in network features of TLE patients. It is not fully understood, however, how these two observations are related., Methods: Using magnetic resonance imaging data, we perform parcellation of the brains of 22 patients with left TLE and 39 non-epileptic controls. In each parcellated region of interest (ROI) we computed the surface area and, using diffusion tensor imaging and deterministic tractography, infer the number of streamlines and their average length between each pair of connected ROIs. For comparison to previous studies, we use a connectivity 'weight' and investigate how ROI surface area, number of streamlines & mean streamline length contribute to such weight., Results: We find that although there are widespread significant changes in surface area and position of ROIs in patients compared to controls, the changes in connectivity are much more subtle. Significant changes in connectivity weight can be accounted for by decreased surface area and increased streamline count., Conclusion: Changes in the surface area of ROIs can be a reliable biomarker for TLE with a large influence on connectivity. However, changes in structural connectivity via white matter streamlines are more subtle with a relatively lower influence on connection weights.

Published

2015

12. From Caenorhabditis elegans to the human connectome: a specific modular organization increases metabolic, functional and developmental efficiency.

Author

Kim JS and Kaiser M

Subjects

Animals, Diffusion Magnetic Resonance Imaging methods, Humans, Species Specificity, Algorithms, Brain anatomy & histology, Brain physiology, Caenorhabditis elegans, Connectome, Models, Neurological

Abstract

The connectome, or the entire connectivity of a neural system represented by a network, ranges across various scales from synaptic connections between individual neurons to fibre tract connections between brain regions. Although the modularity they commonly show has been extensively studied, it is unclear whether the connection specificity of such networks can already be fully explained by the modularity alone. To answer this question, we study two networks, the neuronal network of Caenorhabditis elegans and the fibre tract network of human brains obtained through diffusion spectrum imaging. We compare them to their respective benchmark networks with varying modularities, which are generated by link swapping to have desired modularity values. We find several network properties that are specific to the neural networks and cannot be fully explained by the modularity alone. First, the clustering coefficient and the characteristic path length of both C. elegans and human connectomes are higher than those of the benchmark networks with similar modularity. High clustering coefficient indicates efficient local information distribution, and high characteristic path length suggests reduced global integration. Second, the total wiring length is smaller than for the alternative configurations with similar modularity. This is due to lower dispersion of connections, which means each neuron in the C. elegans connectome or each region of interest in the human connectome reaches fewer ganglia or cortical areas, respectively. Third, both neural networks show lower algorithmic entropy compared with the alternative arrangements. This implies that fewer genes are needed to encode for the organization of neural systems. While the first two findings show that the neural topologies are efficient in information processing, this suggests that they are also efficient from a developmental point of view. Together, these results show that neural systems are organized in such a way as to yield efficient features beyond those given by their modularity alone., (© 2014 The Author(s) Published by the Royal Society. All rights reserved.)

Published

2014

13. Organisational Principles of Connectomes: Changes During Evolution and Development

Author

Bauer, Roman, Kaiser, Marcus, Asami, Takahiro, Series editor, Kajihara, Hiroshi, Series editor, Kobayashi, Kazuya, Series editor, Koizumi, Osamu, Series editor, Motokawa, Masaharu, Series editor, Naruse, Kiyoshi, Series editor, Satoh, Akiko, Series editor, Takamune, Kazufumi, Series editor, Takeuchi, Hideaki, Series editor, Yoshikuni, Michiyasu, Series editor, Shigeno, Shuichi, editor, Murakami, Yasunori, editor, and Nomura, Tadashi, editor

Published

2017

14. Connectomes: from a sparsity of networks to large-scale databases.

Author

Kaiser, Marcus

Subjects

LARGE-scale brain networks, CAENORHABDITIS elegans, FUNCTIONAL connectivity, FRUIT flies, DATABASES

Abstract

The analysis of whole brain networks started in the 1980s when only a handful of connectomes were available. In these early days, information about the human connectome was absent and one could only dream about having information about connectivity in a single human subject. Thanks to non-invasive methods such as diffusion imaging, we now know about connectivity in many species and, for some species, in many individuals. To illustrate the rapid change in availability of connectome data, the UK Biobank is on track to record structural and functional connectivity in 100,000 human subjects. Moreover, connectome data from a range of species is now available: from Caenorhabditis elegans and the fruit fly to pigeons, rodents, cats, non-human primates, and humans. This review will give a brief overview of what structural connectivity data is now available, how connectomes are organized, and how their organization shows common features across species. Finally, I will outline some of the current challenges and potential future work in making use of connectome information. [ABSTRACT FROM AUTHOR]

Published

2023

15. Golgi: Interactive Online Brain Mapping.

Author

Brown, Ramsay A., Swanson, Larry W., Crook, Sharon, and Kaiser, Marcus

Subjects

BRAIN mapping, NEUROANATOMY, NEUROSCIENCES

Abstract

Golgi (http://www.usegolgi.com) is a prototype interactive brain map of the rat brain that helps researchers intuitively interact with neuroanatomy, connectomics, and cellular and chemical architecture. The flood of "-omic" data urges new ways to help researchers connect discrete findings to the larger context of the nervous system. Here we explore Golgi's underlying reasoning and techniques and how our design decisions balance the constraints of building both a scientifically useful and usable tool. We demonstrate how Golgi can enhance connectomic literature searches with a case study investigating a thalamocortical circuit involving the Nucleus Accumbens and we explore Golgi's potential and future directions for growth in systems neuroscience and connectomics. [ABSTRACT FROM AUTHOR]

Published

2015

16. Optimal control based seizure abatement using patient derived connectivity.

Author

Taylor, Peter N., Kaiser, Marcus, Thomas, Jijju, Ruths, Justin, Sinha, Nishant, Dauwels, Justin, and Thesen, Thomas

Subjects

EPILEPSY, ELECTROENCEPHALOGRAPHY, BRAIN stimulation, MAGNETIC resonance imaging, BRAIN mapping

Abstract

Epilepsy is a neurological disorder in which patients have recurrent seizures. Seizures occur in conjunction with abnormal electrical brain activity which can be recorded by the electroencephalogram (EEG). Often, this abnormal brain activity consists of high amplitude regular spike-wave oscillations as opposed to low amplitude irregular oscillations in the non-seizure state. Active brain stimulation has been proposed as a method to terminate seizures prematurely, however, a general and widely-applicable approach to optimal stimulation protocols is still lacking. In this study we use a computational model of epileptic spike-wave dynamics to evaluate the effectiveness of a pseudospectral method to simulated seizure abatement. We incorporate brain connectivity derived from magnetic resonance imaging of a subject with idiopathic generalized epilepsy. We find that the pseudospectral method can successfully generate time-varying stimuli that abate simulated seizures, even when including heterogeneous patient specific brain connectivity. The strength of the stimulus required varies in different brain areas. Our results suggest that seizure abatement, modeled as an optimal control problem and solved with the pseudospectral method, offers an attractive approach to treatment for in vivo stimulation techniques. Further, if optimal brain stimulation protocols are to be experimentally successful, then the heterogeneity of cortical connectivity should be accounted for in the development of those protocols and thus more spatially localized solutions may be preferable. [ABSTRACT FROM AUTHOR]

Published

2015

17. Structural connectivity based whole brain modelling in epilepsy.

Author

Taylor, Peter Neal, Kaiser, Marcus, and Dauwels, Justin

Subjects

*NEUROLOGICAL research, *EPILEPSY, *BRAIN stimulation, *MAGNETIC resonance imaging, *WHITE matter (Nerve tissue)

Abstract

Epilepsy is a neurological condition characterised by the recurrence of seizures. During seizures multiple brain areas can behave abnormally. Rather than considering each abnormal area in isolation, one can consider them as an interconnected functional ‘network’. Recently, there has been a shift in emphasis to consider epilepsy as a disorder involving more widespread functional brain networks than perhaps was previously thought. The basis for these functional networks is proposed to be the static structural brain network established through the connectivity of the white matter. Additionally, it has also been argued that time varying aspects of epilepsy are of crucial importance and as such computational models of these dynamical properties have recently advanced. We describe how dynamic computer models can be combined with static human in vivo connectivity obtained through diffusion weighted magnetic resonance imaging. We predict that in future the use of these two methods in concert will lead to predictions for optimal surgery and brain stimulation sites for epilepsy and other neurological disorders. [ABSTRACT FROM AUTHOR]

Published

2014

18. A tutorial in connectome analysis: Topological and spatial features of brain networks

Author

Kaiser, Marcus

Subjects

*BIOLOGICAL neural networks, *NEUROPHYSIOLOGY, *BRAIN imaging, *CONNECTIONS (Information retrieval system), *NEURONS, *NEURAL circuitry

Abstract

Abstract: High-throughput methods for yielding the set of connections in a neural system, the connectome, are now being developed. This tutorial describes ways to analyze the topological and spatial organizations of the connectome at the macroscopic level of connectivity between brain regions as well as the microscopic level of connectivity between neurons. We will describe topological features at three different levels: the local scale of individual nodes, the regional scale of sets of nodes, and the global scale of the complete set of nodes in a network. Such features can be used to characterize components of a network and to compare different networks, e.g. the connectome of patients and control subjects for clinical studies. At the global scale, different types of networks can be distinguished and we will describe Erdös–Rényi random, scale-free, small-world, modular, and hierarchical archetypes of networks. Finally, the connectome also has a spatial organization and we describe methods for analyzing wiring lengths of neural systems. As an introduction for new researchers in the field of connectome analysis, we discuss the benefits and limitations of each analysis approach. [Copyright &y& Elsevier]

Published

2011

19. Evolution and development of Brain Networks: From Caenorhabditis elegans to Homo sapiens.

Author

Kaiser, Marcus and Varier, Sreedevi

Subjects

*BIOLOGICAL neural networks, *BIOLOGICAL evolution, *CAENORHABDITIS elegans, *HUMAN beings, *HUMAN evolution, *BRAIN evolution

Abstract

Neural networks show a progressive increase in complexity during the time course of evolution. From diffuse nerve nets in Cnidaria to modular, hierarchical systems in macaque and humans, there is a gradual shift from simple processes involving a limited amount of tasks and modalities to complex functional and behavioral processing integrating different kinds of information from highly specialized tissue. However, studies in a range of species suggest that fundamental similarities, in spatial and topological features as well as in developmental mechanisms for network formation, are retained across evolution. 'Small-world' topology and highly connected regions (hubs) are prevalent across the evolutionary scale, ensuring efficient processing and resilience to internal (e.g. lesions) and external (e.g. environment) changes. Furthermore, in most species, even the establishment of hubs, long-range connections linking distant components, and a modular organization, relies on similar mechanisms. In conclusion, evolutionary divergence leads to greater complexity while following essential developmental constraints. [ABSTRACT FROM AUTHOR]

Published

2011

20. Constructive connectomics: How neuronal axons get from here to there using gene-expression maps derived from their family trees

Author

Kerstjens, Stan, Michel, Gabriela, Douglas, Rodney J, University of Zurich, Kaiser, Marcus, and Kerstjens, Stan

Subjects

Leaves, Evolution, 2804 Cellular and Molecular Neuroscience, Mice, Cellular and Molecular Neuroscience, 1311 Genetics, Behavior and Systematics, Connectome, 1312 Molecular Biology, Genetics, Animals, Molecular Biology, 10194 Institute of Neuroinformatics, Neurons, Covariance, Ecology, Gene expression, Axons, Axon guidance, Cell cycle and cell division, Connectomics, Brain, Pedigree, 1105 Ecology, Evolution, Behavior and Systematics, Computational Theory and Mathematics, Modeling and Simulation, 570 Life sciences, biology, 2303 Ecology, 2611 Modeling and Simulation, 1703 Computational Theory and Mathematics

Abstract

During brain development, billions of axons must navigate over multiple spatial scales to reach specific neuronal targets, and so build the processing circuits that generate the intelligent behavior of animals. However, the limited information capacity of the zygotic genome puts a strong constraint on how, and which, axonal routes can be encoded. We propose and validate a mechanism of development that can provide an efficient encoding of this global wiring task. The key principle, confirmed through simulation, is that basic constraints on mitoses of neural stem cells ‒ that mitotic daughters have similar gene expression to their parent and do not stray far from one another ‒ induce a global hierarchical map of nested regions, each marked by the expression profile of its common progenitor population. Thus, a traversal of the lineal hierarchy generates a systematic sequence of expression profiles that traces a staged route, which growth cones can follow to their remote targets. We have analyzed gene expression data of developing and adult mouse brains published by the Allen Institute for Brain Science, and found them consistent with our simulations: gene expression indeed partitions the brain into a global spatial hierarchy of nested contiguous regions that is stable at least from embryonic day 11.5 to postnatal day 56. We use this experimental data to demonstrate that our axonal guidance algorithm is able to robustly extend arbors over long distances to specific targets, and that these connections result in a qualitatively plausible connectome. We conclude that, paradoxically, cell division may be the key to uniting the neurons of the brain., PLoS Computational Biology, 18 (8), ISSN:1553-734X, ISSN:1553-7358

Published

2022