Quantifying morphologies of developing neuronal cells using deep learning with imperfect annotations

IF 2 Q3 NEUROSCIENCES
Amir Masoud Nourollah , Hamid Hassanpour , Amin Zehtabian
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引用次数: 0

Abstract

The functionality of human intelligence relies on the interaction and health of neurons, hence, quantifying neuronal morphologies can be crucial for investigating the functionality of the human brain. This paper proposes a deep learning (DL) based method for segmenting and quantifying neuronal structures in fluorescence microscopy images of developing neuronal cells cultured in vitro. Compared to the majority of supervised DL-based segmentation methods that heavily rely on creating exact corresponding masks of neuronal structures for the preparation of training samples, the proposed approach allows for imperfect annotation of neurons, as it only requires tracing the centrelines of the neurites. This ability accelerates the preparation of training data by several folds. Our proposed framework is built on a modified version of PSPNet with an EfficientNet backbone pre-trained on the CityScapes dataset. To handle the imperfectness of training samples, we incorporated a weighted combination of two loss functions, namely the Dice loss and Lovász loss functions, into our network. We evaluated the proposed framework and several other state-of-the-art methods on a published dataset of approximately 900 manually quantified cultured mouse neurons. Our results indicate a close correlation between the proposed method and manual quantification in terms of neuron length and the number of branches while demonstrating improved analysis speed. Furthermore, the proposed method achieved high accuracy in neuron segmentation, as evidenced by the evaluation of the neurons’ length and number of branches.

利用不完善注释的深度学习量化发育中神经元细胞的形态
人类智能的功能依赖于神经元的相互作用和健康,因此,量化神经元形态对于研究人类大脑的功能至关重要。本文提出了一种基于深度学习(DL)的方法,用于分割和量化体外培养的发育中神经元细胞荧光显微镜图像中的神经元结构。大多数基于深度学习的监督分割方法都严重依赖于创建神经元结构的精确对应掩模来准备训练样本,与之相比,本文提出的方法允许对神经元进行不完全标注,因为它只需要追踪神经元的中心线。这种能力可将训练数据的准备工作加快数倍。我们提出的框架是建立在经过修改的 PSPNet 基础上的,其骨干是在 CityScapes 数据集上预先训练过的 EfficientNet。为了处理训练样本的不完美性,我们在网络中加入了两个损失函数的加权组合,即 Dice 损失函数和 Lovász 损失函数。我们在一个已发布的数据集上对所提出的框架和其他几种最先进的方法进行了评估,该数据集包含约 900 个人工量化培养的小鼠神经元。我们的结果表明,在神经元长度和分支数量方面,所提出的方法与人工量化方法之间具有密切的相关性,同时还提高了分析速度。此外,通过对神经元长度和分支数量的评估,我们提出的方法在神经元分割方面达到了很高的准确度。
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来源期刊
IBRO Neuroscience Reports
IBRO Neuroscience Reports Neuroscience-Neuroscience (all)
CiteScore
2.80
自引率
0.00%
发文量
99
审稿时长
14 weeks
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