Graph-based cell pattern recognition for merging the multi-modal optical microscopic image of neurons

IF 4.9 2区 医学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Computer methods and programs in biomedicine Pub Date : 2024-08-24 DOI:10.1016/j.cmpb.2024.108392
Wenwei Li , Wu Chen , Zimin Dai , Xiaokang Chai , Sile An , Zhuang Guan , Wei Zhou , Jianwei Chen , Hui Gong , Qingming Luo , Zhao Feng , Anan Li
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Abstract

A deep understanding of neuron structure and function is crucial for elucidating brain mechanisms, diagnosing and treating diseases. Optical microscopy, pivotal in neuroscience, illuminates neuronal shapes, projections, and electrical activities. To explore the projection of specific functional neurons, scientists have been developing optical-based multimodal imaging strategies to simultaneously capture dynamic in vivo signals and static ex vivo structures from the same neuron. However, the original position of neurons is highly susceptible to displacement during ex vivo imaging, presenting a significant challenge for integrating multimodal information at the single-neuron level. This study introduces a graph-model-based approach for cell image matching, facilitating precise and automated pairing of sparsely labeled neurons across different optical microscopic images. It has been shown that utilizing neuron distribution as a matching feature can mitigate modal differences, the high-order graph model can address scale inconsistency, and the nonlinear iteration can resolve discrepancies in neuron density. This strategy was applied to the connectivity study of the mouse visual cortex, performing cell matching between the two-photon calcium image and the HD-fMOST brain-wide anatomical image sets. Experimental results demonstrate 96.67% precision, 85.29% recall rate, and 90.63% F1 Score, comparable to expert technicians. This study builds a bridge between functional and structural imaging, offering crucial technical support for neuron classification and circuitry analysis.

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基于图谱的细胞模式识别,用于合并神经元的多模态光学显微图像
深入了解神经元的结构和功能对于阐明大脑机制、诊断和治疗疾病至关重要。光学显微镜在神经科学中举足轻重,它能照亮神经元的形状、投射和电活动。为了探索特定功能神经元的投射,科学家们一直在开发基于光学的多模态成像策略,以同时捕捉同一神经元的动态体内信号和静态体外结构。然而,神经元的原始位置极易在体外成像过程中发生位移,这给在单神经元水平整合多模态信息带来了巨大挑战。本研究介绍了一种基于图模型的细胞图像匹配方法,有助于不同光学显微图像中稀疏标记神经元的精确自动配对。研究表明,利用神经元分布作为匹配特征可减轻模态差异,高阶图模型可解决尺度不一致问题,非线性迭代可解决神经元密度差异问题。这一策略被应用于小鼠视觉皮层的连接性研究,在双光子钙离子图像和 HD-fMOST 全脑解剖图像集之间进行细胞匹配。实验结果表明,精确度为 96.67%,召回率为 85.29%,F1 分数为 90.63%,与专家技术人员不相上下。这项研究在功能成像和结构成像之间架起了一座桥梁,为神经元分类和电路分析提供了重要的技术支持。
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来源期刊
Computer methods and programs in biomedicine
Computer methods and programs in biomedicine 工程技术-工程:生物医学
CiteScore
12.30
自引率
6.60%
发文量
601
审稿时长
135 days
期刊介绍: To encourage the development of formal computing methods, and their application in biomedical research and medical practice, by illustration of fundamental principles in biomedical informatics research; to stimulate basic research into application software design; to report the state of research of biomedical information processing projects; to report new computer methodologies applied in biomedical areas; the eventual distribution of demonstrable software to avoid duplication of effort; to provide a forum for discussion and improvement of existing software; to optimize contact between national organizations and regional user groups by promoting an international exchange of information on formal methods, standards and software in biomedicine. Computer Methods and Programs in Biomedicine covers computing methodology and software systems derived from computing science for implementation in all aspects of biomedical research and medical practice. It is designed to serve: biochemists; biologists; geneticists; immunologists; neuroscientists; pharmacologists; toxicologists; clinicians; epidemiologists; psychiatrists; psychologists; cardiologists; chemists; (radio)physicists; computer scientists; programmers and systems analysts; biomedical, clinical, electrical and other engineers; teachers of medical informatics and users of educational software.
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