A novel deep learning-based method for automatic stereology of microglia cells from low magnification images

IF 2.6 3区 医学 Q3 NEUROSCIENCES Neurotoxicology and teratology Pub Date : 2024-03-01 DOI:10.1016/j.ntt.2024.107336
Hunter Morera , Palak Dave , Yaroslav Kolinko , Saeed Alahmari , Aidan Anderson , Grant Denham , Chloe Davis , Juan Riano , Dmitry Goldgof , Lawrence O. Hall , G. Jean Harry , Peter R. Mouton
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Abstract

Microglial cells mediate diverse homeostatic, inflammatory, and immune processes during normal development and in response to cytotoxic challenges. During these functional activities, microglial cells undergo distinct numerical and morphological changes in different tissue volumes in both rodent and human brains. However, it remains unclear how these cytostructural changes in microglia correlate with region-specific neurochemical functions. To better understand these relationships, neuroscientists need accurate, reproducible, and efficient methods for quantifying microglial cell number and morphologies in histological sections. To address this deficit, we developed a novel deep learning (DL)-based classification, stereology approach that links the appearance of Iba1 immunostained microglial cells at low magnification (20×) with the total number of cells in the same brain region based on unbiased stereology counts as ground truth. Once DL models are trained, total microglial cell numbers in specific regions of interest can be estimated and treatment groups predicted in a high-throughput manner (<1 min) using only low-power images from test cases, without the need for time and labor-intensive stereology counts or morphology ratings in test cases. Results for this DL-based automatic stereology approach on two datasets (total 39 mouse brains) showed >90% accuracy, 100% percent repeatability (Test-Retest) and 60× greater efficiency than manual stereology (<1 min vs. ∼ 60 min) using the same tissue sections. Ongoing and future work includes use of this DL-based approach to establish clear neurodegeneration profiles in age-related human neurological diseases and related animal models.

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基于深度学习的小胶质细胞自动立体成像新方法
小神经胶质细胞在正常发育过程中以及在应对细胞毒性挑战时介导多种平衡、炎症和免疫过程。在这些功能活动中,小胶质细胞在啮齿动物和人类大脑的不同组织体积中会发生不同的数量和形态变化。然而,小胶质细胞的这些细胞结构变化如何与特定区域的神经化学功能相关联,目前仍不清楚。为了更好地理解这些关系,神经科学家需要准确、可重复和高效的方法来量化组织学切片中的小胶质细胞数量和形态。为了解决这一不足,我们开发了一种新颖的基于深度学习(DL)的分类、立体学方法,该方法将低倍放大(20×)下 Iba1 免疫染色小胶质细胞的外观与同一脑区的细胞总数联系起来,以无偏见的立体学计数为基本事实。DL 模型训练完成后,只需使用测试病例的低倍图像,就能以高通量方式(1 分钟)估算出特定相关区域的小胶质细胞总数并预测治疗组别,而无需在测试病例中进行耗时耗力的立体计数或形态评级。这种基于 DL 的自动立体学方法在两个数据集(共 39 个小鼠大脑)上的结果显示,在使用相同组织切片的情况下,其准确率为 90%,重复性为 100% (测试-重测),效率比人工立体学高 60 倍(1 分钟 vs. ∼ 60 分钟)。正在进行的和未来的工作包括使用这种基于 DL 的方法在与年龄相关的人类神经系统疾病和相关动物模型中建立清晰的神经变性特征。
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来源期刊
CiteScore
5.60
自引率
10.30%
发文量
48
审稿时长
58 days
期刊介绍: Neurotoxicology and Teratology provides a forum for publishing new information regarding the effects of chemical and physical agents on the developing, adult or aging nervous system. In this context, the fields of neurotoxicology and teratology include studies of agent-induced alterations of nervous system function, with a focus on behavioral outcomes and their underlying physiological and neurochemical mechanisms. The Journal publishes original, peer-reviewed Research Reports of experimental, clinical, and epidemiological studies that address the neurotoxicity and/or functional teratology of pesticides, solvents, heavy metals, nanomaterials, organometals, industrial compounds, mixtures, drugs of abuse, pharmaceuticals, animal and plant toxins, atmospheric reaction products, and physical agents such as radiation and noise. These reports include traditional mammalian neurotoxicology experiments, human studies, studies using non-mammalian animal models, and mechanistic studies in vivo or in vitro. Special Issues, Reviews, Commentaries, Meeting Reports, and Symposium Papers provide timely updates on areas that have reached a critical point of synthesis, on aspects of a scientific field undergoing rapid change, or on areas that present special methodological or interpretive problems. Theoretical Articles address concepts and potential mechanisms underlying actions of agents of interest in the nervous system. The Journal also publishes Brief Communications that concisely describe a new method, technique, apparatus, or experimental result.
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