Abstract
BackgroundThe locations and shapes of synapses are important in reconstructing connectomes and analyzing synaptic plasticity. However, current synapse detection and segmentation methods are still not adequate for accurately acquiring the synaptic connectivity, and they cannot effectively alleviate the burden of synapse validation.ResultsWe propose a fully automated method that relies on deep learning to realize the 3D reconstruction of synapses in electron microscopy (EM) images. The proposed method consists of three main parts: (1) training and employing the faster region convolutional neural networks (R-CNN) algorithm to detect synapses, (2) using the z-continuity of synapses to reduce false positives, and (3) combining the Dijkstra algorithm with the GrabCut algorithm to obtain the segmentation of synaptic clefts. Experimental results were validated by manual tracking, and the effectiveness of our proposed method was demonstrated. The experimental results in anisotropic and isotropic EM volumes demonstrate the effectiveness of our algorithm, and the average precision of our detection (92.8% in anisotropy, 93.5% in isotropy) and segmentation (88.6% in anisotropy, 93.0% in isotropy) suggests that our method achieves state-of-the-art results.ConclusionsOur fully automated approach contributes to the development of neuroscience, providing neurologists with a rapid approach for obtaining rich synaptic statistics.
Highlights
The locations and shapes of synapses are important in reconstructing connectomes and analyzing synaptic plasticity
A synapse is a structure that permits a neuron to pass an electrical or chemical signal to another neuron, and it has an important responsibility in the neural system
If we consider the brain network to be a map of connections, neurons and synapses can be considered as the dots and lines, respectively, and it can be hypothesized that the synapse is one of the key factors for researching connectomes [1,2,3]
Summary
The locations and shapes of synapses are important in reconstructing connectomes and analyzing synaptic plasticity. A synapse is a structure that permits a neuron (or nerve cell) to pass an electrical or chemical signal to another neuron, and it has an important responsibility in the neural system. If we consider the brain network to be a map of connections, neurons and synapses can be considered as the dots and lines, respectively, and it can be hypothesized that the synapse is one of the key factors for researching connectomes [1,2,3]. Synaptic plasticity is associated with learning and memory. According to the classification of synaptic nerve impulses, there are two types of synapses: chemical synapses and electrical synapses. It is possible to more closely examine the synapse structure
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