A Topological Representation of Branching Neuronal Morphologies

Kanari, Lida; Dłotko, Paweł; Scolamiero, Martina; Levi, Ran; Shillcock, Julian C.; Hess, Kathryn; Markram, Henry

doi:10.1007/s12021-017-9341-1

Cited by 165 publications

(225 citation statements)

References 45 publications

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“…For example, astrocyte mini‐circuits might adopt feed‐forward, recurrent or mixed patterns, depending on the behavioral task, and present hierarchical organizations between astrocytic and neuronal elements, as well as topological/functional “motifs” and wiring rules—as shown in the analysis of small neuronal networks (Schroter, Paulsen, & Bullmore, ). Tools for connectomics include graph theory (Fornito, Zalesky, & Bullmore, ), Bayesian hierarchical modeling (Bishop, ), and topological tools (Kanari et al, ; Reimann et al, ). In all these approaches, both morphological and functional readouts could serve as input data.…”

Section: A Roadmap To Advance the Integration Of Astrocytes Into Systmentioning

confidence: 99%

“…and wiring rules-as shown in the analysis of small neuronal networks (Schroter, Paulsen, & Bullmore, 2017). Tools for connectomics include graph theory (Fornito, Zalesky, & Bullmore, 2016), Bayesian hierarchical modeling (Bishop, 2006), and topological tools (Kanari et al, 2018;Reimann et al, 2017). In all these approaches, both morphological and functional readouts could serve as input data.…”

Section: Connectomicsmentioning

confidence: 99%

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A roadmap to integrate astrocytes into Systems Neuroscience

Kastanenka

Moreno-Bote

Pittà

et al. 2019

Glia

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Systems neuroscience is still mainly a neuronal field, despite the plethora of evidence supporting the fact that astrocytes modulate local neural circuits, networks, and complex behaviors. In this article, we sought to identify which types of studies are necessary to establish whether astrocytes, beyond their well‐documented homeostatic and metabolic functions, perform computations implementing mathematical algorithms that sub‐serve coding and higher‐brain functions. First, we reviewed Systems‐like studies that include astrocytes in order to identify computational operations that these cells may perform, using Ca2+ transients as their encoding language. The analysis suggests that astrocytes may carry out canonical computations in a time scale of subseconds to seconds in sensory processing, neuromodulation, brain state, memory formation, fear, and complex homeostatic reflexes. Next, we propose a list of actions to gain insight into the outstanding question of which variables are encoded by such computations. The application of statistical analyses based on machine learning, such as dimensionality reduction and decoding in the context of complex behaviors, combined with connectomics of astrocyte–neuronal circuits, is, in our view, fundamental undertakings. We also discuss technical and analytical approaches to study neuronal and astrocytic populations simultaneously, and the inclusion of astrocytes in advanced modeling of neural circuits, as well as in theories currently under exploration such as predictive coding and energy‐efficient coding. Clarifying the relationship between astrocytic Ca2+ and brain coding may represent a leap forward toward novel approaches in the study of astrocytes in health and disease.

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Section: A Roadmap To Advance the Integration Of Astrocytes Into Systmentioning

confidence: 99%

Section: Connectomicsmentioning

confidence: 99%

A roadmap to integrate astrocytes into Systems Neuroscience

Kastanenka

Moreno-Bote

Pittà

et al. 2019

Glia

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“…Finally, we used persistence images, a recently introduced quantification of neural morphology based on topological ideas Kanari et al, 2018Kanari et al, , 2019. We used four different distance functions (also called filter functions) to construct one-and two-dimensional persistence images, resulting in eight different persistence representations.…”

Section: Morphological Feature Representationsmentioning

confidence: 99%

“…Persistence diagrams originate from the field of algebraic topology but recently have been proposed as a representation for neural morphologies (Kanari et al, 2018). We briefly outline their underlying algorithm here.…”

Section: Persistence Diagramsmentioning

confidence: 99%

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A systematic evaluation of interneuron morphology representations for cell type discrimination

Laturnus

Kobak

Berens

2019

Preprint

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AbstractQuantitative analysis of neuronal morphologies usually begins with choosing a particular feature representation in order to make individual morphologies amenable to standard statistics tools and machine learning algorithms. Many different feature representations have been suggested in the literature, ranging from density maps to intersection profiles, but they have never been compared side by side. Here we performed a systematic comparison of various representations, measuring how well they were able to capture the difference between known morphological cell types. For our benchmarking effort, we used several curated data sets consisting of mouse retinal bipolar cells and cortical inhibitory neurons. We found that the best performing feature representations were two-dimensional density maps closely followed by morphometric statistics, which both continued to perform well even when neurons were only partially traced. The same representations performed well in an unsupervised setting, implying that they can be suitable for dimensionality reduction or clustering.

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Cell morphologies in the nervous system: Glia steal the limelight

Ascoli

2022

J of Comparative Neurology

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Neurons and glia have distinct yet interactive functions but are both characterized by branching morphology. Dendritic trees have been digitally traced for over 40 years in many animal species, anatomical regions, and neuron types. Recently, long-range axons also are being reconstructed throughout the brain of many organisms from invertebrates to primates. In contrast, less attention has been paid until lately to glial morphology. Thus, although glia and neurons are similarly abundant in the nervous systems of humans and most animal models, glia have traditionally been much less represented than neurons in morphological reconstruction repositories such as Neu-roMorpho.Org. This is rapidly changing with the advent of high-throughput glia tracing.NeuroMorpho.Org introduced glial cells in 2017 and today they constitute nearly a third of the database content. It took NeuroMorpho.Org 10 years to collect the first 40,000 neurons and now that amount of data can be produced in a single publication.This not only demonstrates the spectacular technological progress in data production, but also demands a corresponding advancement in informatics processing. At the same time, these publicly available data also open new opportunities for quantitative analysis and computational modeling to identify universal or cell-type-specific design principles in the cellular architecture of nervous systems. As a first application, we demonstrated that supervised machine learning of tree geometry classifies neurons and glia with practically perfect accuracy. Furthermore, we discovered a new morphometric biomarker capable of robustly separating these cell classes across multiple species, brain regions, and experimental preparations, with only sparse sampling of branch measurements.The nervous systems of almost all animals consist of two distinct, yet functionally interactive, cellular families: neurons and glia. Both of these constituents are characterized by branching morphologies. The trees stemming from glial cell bodies, referred to as processes, serve a variety of functions depending on the cell type, including myelination in oligodendrocytes, immune reactivity in microglia, and metabolic regulation in astrocytes. Most neurons emanate from their somas separate arbors specialized in signaling input (dendrites) and outputThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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A Topological Representation of Branching Neuronal Morphologies

Cited by 165 publications

References 45 publications

A roadmap to integrate astrocytes into Systems Neuroscience

A roadmap to integrate astrocytes into Systems Neuroscience

A systematic evaluation of interneuron morphology representations for cell type discrimination

Cell morphologies in the nervous system: Glia steal the limelight

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