Detecting Synapse Location and Connectivity by Signed Proximity Estimation and Pruning with Deep Nets

Parag, Toufiq; Berger, Daniel R.; Kamentsky, Lee; Staffler, Benedikt; Wei, Donglai; Helmstaedter, Moritz; Lichtman, Jeff W.; Pfister, Hanspeter

doi:10.1007/978-3-030-11024-6_25

Cited by 7 publications

(6 citation statements)

References 23 publications

(52 reference statements)

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“…The method has a few limitations, too. First, the reconstruction is a prerequisite ( Staffler et al, 2017 ; Parag et al, 2018 ; Buhmann et al, 2021 ). Other methods are needed if a researcher wants to reconstruct only a few neurons first, find their synapses, and then backward trace the synaptic partners of the first neurons from the synapses.…”

Section: Discussionmentioning

confidence: 99%

Automated Synapse Detection Method for Cerebellar Connectomics

et al. 2022

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The connectomic analyses of large-scale volumetric electron microscope (EM) images enable the discovery of hidden neural connectivity. While the technologies for neuronal reconstruction of EM images are under rapid progress, the technologies for synapse detection are lagging behind. Here, we propose a method that automatically detects the synapses in the 3D EM images, specifically for the mouse cerebellar molecular layer (CML). The method aims to accurately detect the synapses between the reconstructed neuronal fragments whose types can be identified. It extracts the contacts between the reconstructed neuronal fragments and classifies them as synaptic or non-synaptic with the help of type information and two deep learning artificial intelligences (AIs). The method can also assign the pre- and postsynaptic sides of a synapse and determine excitatory and inhibitory synapse types. The accuracy of this method is estimated to be 0.955 in F1-score for a test volume of CML containing 508 synapses. To demonstrate the usability, we measured the size and number of the synapses in the volume and investigated the subcellular connectivity between the CML neuronal fragments. The basic idea of the method to exploit tissue-specific properties can be extended to other brain regions.

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Section: Discussionmentioning

confidence: 99%

Automated Synapse Detection Method for Cerebellar Connectomics

et al. 2022

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“…Although manual annotation to analyze synapses is straightforward, it is not ideal for analysis of their density as a function of proximity to a plaque, given their large number. We thus used machine-learning-based automated synapse detection (Buhmann et al, 2021;Çiçek et al, 2016;Lin et al, 2021;Parag et al, 2019;Santurkar et al, 2017;Staffler et al, 2017;Su et al, 2023), which has been performed on large-scale connectomics datasets (Scheffer et al, 2020;Shapson-Coe et al, 2021;Turner et al, 2022) and proved to be time-efficient, unbiased and accurate.…”

Section: D Reconstructions Of Neurons With Intraneuronal Aβ or Ptau S...mentioning

confidence: 99%

A large-scale volumetric correlated light and electron microscopy study localizes Alzheimer’s disease-related molecules in the hippocampus

Han,

Li,

Wang

et al. 2023

Preprint

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Connectomics is a nascent neuroscience field to map and analyze neuronal networks. It provides a new way to investigate abnormalities in brain tissue, including in models of Alzheimer's disease (AD). This age-related disease is associated with alterations in amyloid-β (Aβ) and phosphorylated tau (pTau). These alterations correlate with AD's clinical manifestations, but causal links remain unclear. Therefore, studying these molecular alterations within the context of the local neuronal and glial milieu may provide insight into disease mechanisms. Volume electron microscopy (vEM) is an ideal tool for performing connectomics studies at the ultrastructural level, but localizing specific biomolecules within large-volume vEM data has been challenging. Here we report a volumetric correlated light and electron microscopy (vCLEM) approach using fluorescent nanobodies as immuno-probes to localize Alzheimer's disease-related molecules in a large vEM volume. Three molecules (pTau, Aβ, and a marker for activated microglia (CD11b)) were labeled without the need for detergents by three nanobody probes in a sample of the hippocampus of the 3xTg Alzheimer's disease model mouse. Confocal microscopy followed by vEM imaging of the same sample allowed for registration of the location of the molecules within the volume. This dataset revealed several ultrastructural abnormalities regarding the localizations of Aβ and pTau in novel locations. For example, two pTau-positive post-synaptic spine-like protrusions innervated by axon terminals were found projecting from the axon initial segment of a pyramidal cell. Three pyramidal neurons with intracellular Aβ or pTau were 3D reconstructed. Automatic synapse detection, which is necessary for connectomics analysis, revealed the changes in density and volume of synapse at different distances from an Aβ plaque. This vCLEM approach is useful to uncover molecular alterations within large-scale volume electron microscopy data, opening a new connectomics pathway to study Alzheimer's disease and other types of dementia.

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“…A number of approaches are used to find the partner neurons at a synaptic cleft [64,66,58,67,70]. For example, Dorkenwald et al [58] extract features relating the predicted cleft segments to candidate partners by overlap with these partners, as well as their contact site, and feed these features to a random forest classifier for a final "synaptic" or "non-synaptic" classification for inferring connectivity.…”

Section: Synaptic Relationshipsmentioning

confidence: 99%

“…For example, Dorkenwald et al [58] extract features relating the predicted cleft segments to candidate partners by overlap with these partners, as well as their contact site, and feed these features to a random forest classifier for a final "synaptic" or "non-synaptic" classification for inferring connectivity. Parag et al [70] pass a candidate cleft, local image context, and a candidate pair of partner segments to a convolutional net to make a similar "synaptic" or "non-synaptic" judgment. Turner et al [71] use a similar model, yet they instead use the cleft as an attentional input to predict the voxels of relevant presynaptic and postsynaptic partners.…”

Section: Synaptic Relationshipsmentioning

confidence: 99%

Convolutional nets for reconstructing neural circuits from brain images acquired by serial section electron microscopy

Lee¹,

Turner

Macrina

et al. 2019

Current Opinion in Neurobiology

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Neural circuits can be reconstructed from brain images acquired by serial section electron microscopy. Image analysis has been performed by manual labor for half a century, and efforts at automation date back almost as far. Convolutional nets were first applied to neuronal boundary detection a dozen years ago, and have now achieved impressive accuracy on clean images. Robust handling of image defects is a major outstanding challenge. Convolutional nets are also being employed for other tasks in neural circuit reconstruction: finding synapses and identifying synaptic partners, extending or pruning neuronal reconstructions, and aligning serial section images to create a 3D image stack. Computational systems are being engineered to handle petavoxel images of cubic millimeter brain volumes.

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Detecting Synapse Location and Connectivity by Signed Proximity Estimation and Pruning with Deep Nets

Cited by 7 publications

References 23 publications

Automated Synapse Detection Method for Cerebellar Connectomics

Automated Synapse Detection Method for Cerebellar Connectomics

A large-scale volumetric correlated light and electron microscopy study localizes Alzheimer’s disease-related molecules in the hippocampus

Convolutional nets for reconstructing neural circuits from brain images acquired by serial section electron microscopy

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