Objective Morphological Classification of Neocortical Pyramidal Cells

Kanari, Lida; Ramaswamy, Srikanth; Shi, Ying; Morand, Sebastien; Meystre, Julie; Perin, Rodrigo; Abdellah, Marwan; Wang, Yun; Hess, Kathryn; Markram, Henry

doi:10.1093/cercor/bhy339

Cited by 87 publications

(93 citation statements)

References 77 publications

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“…For example, they failed to distinguish double-bouquet cells and Martinotti cells in layer 4. Various forms of persistence-based measures performed consistently worse than density maps, at least for the interneurons studied here (originally, persistence diagrams were developed for cortical pyramidal neurons (Adams et al, 2017;Kanari et al, 2019;). We did not extensively evaluate combinations of feature representations, as combining even the best representations did not dramatically improve performance, possible as a result of overfitting to a data set of limited size (see Figure 5).…”

Section: Previous Literaturementioning

confidence: 85%

“…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%

“…Morphometric statistics have been used in a wide variety of studies across species and brain areas (Lu et al, 2013;Polavaram et al, 2014;Lu et al, 2015;Gouwens et al, 2018) and have been shown to perform well in a one-vs-rest classification of cortical neurons (Mihaljević et al, 2015(Mihaljević et al, , 2018. Persistence, in turn, has lately been shown to distinguish pyramidal neuron types in juvenile rat somatosensory cortex (Kanari et al, 2019). These studies, however, did not directly compare different morphology representations, but rather focused on comparing classification schemes or establishing cell type related differences within their chosen morphological representation.…”

Section: Previous Literaturementioning

confidence: 99%

“…Euclidean distance is undefined for persistence diagrams themselves. To circumvent this problem we converted each persistence diagram into a 1D or 2D image and used Euclidean distance on the results as this procedure has been shown to work well in the neural domain (Kanari et al, 2019;.…”

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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Section: Previous Literaturementioning

confidence: 85%

Section: Morphological Feature Representationsmentioning

confidence: 99%

Section: Previous Literaturementioning

confidence: 99%

Section: Persistence Diagramsmentioning

confidence: 99%

See 2 more Smart Citations

A systematic evaluation of interneuron morphology representations for cell type discrimination

Laturnus

Kobak

Berens

2019

Preprint

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“…This approach requires sparse labeling of genetically or lineage-related cell types, which is facilitated by transgenic drivers and viral vectors (Harris et al 2014; He et al 2016). Paired with advancements in statistical and computational methods, neuronal subtypes can be effectively parsed using single neuron anatomy, as illustrated for sensory afferents in the skin (Wu et al 2012), olfactory bulb neurons (Tavakoli et al 2018), and pyramidal and GABAergic interneurons in the cortex ; Kanari et al 2019; Gouwens et al 2019). Drawing fine divisions between subtypes can be challenging however, as heterogeneity and continuous variation within cell types are commonly observed (Cembrowski and Scala et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Morphological pseudotime ordering and fate mapping reveals diversification of cerebellar inhibitory interneurons

Wang

Lefebvre

2020

Preprint

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Understanding how diverse neurons are assembled into circuits requires a framework for describing cell types and their developmental trajectories. Here, we combined genetic fate mapping and pseudo-temporal profiling to resolve the diversification of cerebellar inhibitory interneurons based on morphology. The molecular layer interneurons (MLIs) derive from a common progenitor but comprise a diverse population of dendritic-, somatic-, and axon initial segment-targeting interneurons. MLIs are classically divided into two types. However, their morphological heterogeneity suggests an alternate model of one continuously varying population. Through clustering and trajectory inference of 811 MLI reconstructions at maturity and during development, we show that MLIs divide into two discrete classes but also present significant within-class heterogeneity. Pseudotime trajectory mapping uncovered the emergence of distinct phenotypes during migration and axonogenesis, well before neurons reach their final positions. Our study illustrates the utility of quantitative single-cell methods to morphology for defining the diversification of neuronal subtypes. Figure 2. Morphological heterogeneity among MLIs. (A) Left: Immunostaining of MLIs (Parvalbumin, cyan) and PCs (co-labeled by Parvalbumin and Calbindin, cyan and red, respectively) show the ML space in which MLIs reside. PC somata are enveloped by BC axons (white arrowhead). Right: Inverted image of four fluorescently-labelled MLIs. The lower MLI (pink arrowhead) has canonical BC morphologies, including axonal basket terminals around the PC somata (asterisks). The two upper MLIs (teal arrowhead) have canonical SC morphologies and reside within the upper ML. The faintly labelled MLI (blue arrowhead) has SC morphologies but reside within the lower ML. (B) Reconstruction of canonical BC from panel A, with complete dendritic arbor traced in orange, and complete axonal arbor traced in blue. (C) Reconstruction of canonical SC from panel A (cell on far right). (D-F) Representative images of MLIs with mixtures of BC and SC characteristics. Top: inverted fluorescence image; Bottom: reconstruction with dendritic (orange) and axonal (blue) traces. (D) MLI located in the middle ML with SC dendritic features, and a long horizontal axon (arrow) with descending basket collaterals (asterisks). (E) MLI located in the lower ML with SC-like dendritic and axonal arbors. (F) MLI located in the upper ML with a long horizontal axon (arrow) and two descending axon collaterals with basket formations around PC somas (asterisks). All scale bars are 50 μm.

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Topological Adventures in Neuroscience

Hess

2020

Topological Data Analysis

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Objective Morphological Classification of Neocortical Pyramidal Cells

Cited by 87 publications

References 77 publications

A systematic evaluation of interneuron morphology representations for cell type discrimination

A systematic evaluation of interneuron morphology representations for cell type discrimination

Morphological pseudotime ordering and fate mapping reveals diversification of cerebellar inhibitory interneurons

Topological Adventures in Neuroscience

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