A guide to CNN-based dense segmentation of neuronal EM images.

Microscopy (Oxford, England) Pub Date : 2025-01-13 DOI:10.1093/jmicro/dfaf002

Hidetoshi Urakubo

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Abstract

Large-scale reconstitution of neuronal circuits from volumetric electron microscopy images is a remarkable research goal in neuroanatomy. However, the large-scale reconstruction is a result of automatic segmentation using convolutional neural networks (CNNs), which is still challenging for general researchers to perform. This review focuses on two representative CNNs for dense neuronal segmentation: flood-filling networks (FFN) and local shape descriptors (LSD)-predicting U-Net (LSD network). It outlines their basic mechanisms, requirements, and output segmentation using author's example segmentation. The FFN excels in segmenting long axons, and the LSD network is adept at segmenting myelinated axons. The choice between FFN and LSD depends on the target, as neither is universally superior. A common limitation of FFN and LSD is the easy detachment of thin spines from parent dendrites, which is fundamentally unavoidable. The author also introduces CNNs proposed to mitigate this issue. As CNN-based automated segmentation can take months, researchers need to be aware of the selection of an appropriate CNN, required computer resources, and fundamental limitations. This review serves as a guide for such dense neuronal segmentation.

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基于cnn的神经元EM图像密集分割指南。

从体积电子显微镜图像中大规模重建神经回路是神经解剖学中一个重要的研究目标。然而，大规模重建是卷积神经网络（cnn）自动分割的结果，这对一般研究人员来说仍然是一个挑战。本文综述了两种具有代表性的密集神经元分割cnn：洪水填充网络（FFN）和局部形状描述符（LSD）预测U-Net （LSD网络）。它概述了它们的基本机制、需求和使用作者的示例分割的输出分割。FFN擅长分割长轴突，LSD擅长分割髓鞘轴突。在FFN和LSD之间的选择取决于目标，因为两者都不是普遍的优越。FFN和LSD的一个共同限制是薄棘容易从母枝上脱离，这基本上是不可避免的。作者还介绍了cnn提出的缓解这一问题的方法。由于基于CNN的自动分割可能需要几个月的时间，研究人员需要意识到选择合适的CNN，所需的计算机资源和基本限制。这篇综述为这种密集的神经元分割提供了指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Microscopy (Oxford, England)

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