Polymer Physics-Based Classification of Neurons.

IF 2.7 4区 医学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Neuroinformatics Pub Date : 2023-01-01 DOI:10.1007/s12021-022-09605-3
Kiri Choi, Won Kyu Kim, Changbong Hyeon
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引用次数: 2

Abstract

Recognizing that diverse morphologies of neurons are reminiscent of structures of branched polymers, we put forward a principled and systematic way of classifying neurons that employs the ideas of polymer physics. In particular, we use 3D coordinates of individual neurons, which are accessible in recent neuron reconstruction datasets from electron microscope images. We numerically calculate the form factor, F(q), a Fourier transform of the distance distribution of particles comprising an object of interest, which is routinely measured in scattering experiments to quantitatively characterize the structure of materials. For a polymer-like object consisting of n monomers spanning over a length scale of r, F(q) scales with the wavenumber [Formula: see text] as [Formula: see text] at an intermediate range of q, where [Formula: see text] is the fractal dimension or the inverse scaling exponent ([Formula: see text]) characterizing the geometrical feature ([Formula: see text]) of the object. F(q) can be used to describe a neuron morphology in terms of its size ([Formula: see text]) and the extent of branching quantified by [Formula: see text]. By defining the distance between F(q)s as a measure of similarity between two neuronal morphologies, we tackle the neuron classification problem. In comparison with other existing classification methods for neuronal morphologies, our F(q)-based classification rests solely on 3D coordinates of neurons with no prior knowledge of morphological features. When applied to publicly available neuron datasets from three different organisms, our method not only complements other methods but also offers a physical picture of how the dendritic and axonal branches of an individual neuron fill the space of dense neural networks inside the brain.

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基于聚合物物理的神经元分类。
认识到神经元的不同形态与分支聚合物的结构相似,我们提出了一种原则性的、系统的神经元分类方法,该方法采用了聚合物物理学的思想。特别是,我们使用了单个神经元的三维坐标,这可以从最近的电子显微镜图像中获得神经元重建数据集。我们在数值上计算形状因子F(q),这是包含感兴趣对象的粒子距离分布的傅里叶变换,这是在散射实验中常规测量的,以定量表征材料的结构。对于由n个单体组成的聚合物类物体,其长度范围为r, F(q)的波数[公式:见文]在中间范围为q,其中[公式:见文]是表征物体几何特征([公式:见文])的分形维数或逆标度指数([公式:见文])。F(q)可以用来描述神经元形态的大小([公式:见文])和分支的程度量化[公式:见文]。通过定义F(q)s之间的距离作为两个神经元形态之间相似性的度量,我们解决了神经元分类问题。与其他现有的神经元形态分类方法相比,我们的基于F(q)的分类仅仅依赖于神经元的三维坐标,没有形态学特征的先验知识。当应用于来自三种不同生物体的公开可用的神经元数据集时,我们的方法不仅补充了其他方法,而且还提供了单个神经元的树突和轴突分支如何填充大脑内部密集神经网络空间的物理图像。
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来源期刊
Neuroinformatics
Neuroinformatics 医学-计算机:跨学科应用
CiteScore
6.00
自引率
6.70%
发文量
54
审稿时长
3 months
期刊介绍: Neuroinformatics publishes original articles and reviews with an emphasis on data structure and software tools related to analysis, modeling, integration, and sharing in all areas of neuroscience research. The editors particularly invite contributions on: (1) Theory and methodology, including discussions on ontologies, modeling approaches, database design, and meta-analyses; (2) Descriptions of developed databases and software tools, and of the methods for their distribution; (3) Relevant experimental results, such as reports accompanie by the release of massive data sets; (4) Computational simulations of models integrating and organizing complex data; and (5) Neuroengineering approaches, including hardware, robotics, and information theory studies.
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