A deep learning pipeline for three-dimensional brain-wide mapping of local neuronal ensembles in teravoxel light-sheet microscopy

IF 28.3 1区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS Nature Methods Pub Date : 2025-01-27 DOI:10.1038/s41592-024-02583-1
Ahmadreza Attarpour, Jonas Osmann, Anthony Rinaldi, Tianbo Qi, Neeraj Lal, Shruti Patel, Matthew Rozak, Fengqing Yu, Newton Cho, Jordan Squair, JoAnne McLaurin, Misha Raffiee, Karl Deisseroth, Gregoire Courtine, Li Ye, Bojana Stefanovic, Maged Goubran
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Abstract

Teravoxel-scale, cellular-resolution images of cleared rodent brains acquired with light-sheet fluorescence microscopy have transformed the way we study the brain. Realizing the potential of this technology requires computational pipelines that generalize across experimental protocols and map neuronal activity at the laminar and subpopulation-specific levels, beyond atlas-defined regions. Here, we present artficial intelligence-based cartography of ensembles (ACE), an end-to-end pipeline that employs three-dimensional deep learning segmentation models and advanced cluster-wise statistical algorithms, to enable unbiased mapping of local neuronal activity and connectivity. Validation against state-of-the-art segmentation and detection methods on unseen datasets demonstrated ACE’s high generalizability and performance. Applying ACE in two distinct neurobiological contexts, we discovered subregional effects missed by existing atlas-based analyses and showcase ACE’s ability to reveal localized or laminar neuronal activity brain-wide. Our open-source pipeline enables whole-brain mapping of neuronal ensembles at a high level of precision across a wide range of neuroscientific applications. The ACE pipeline utilized deep learning and advanced statistics for mapping neural activity at a granular level that is independent of atlas-defined regions.

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三像素光片显微镜中局部神经元集合的三维全脑映射的深度学习管道。
用光片荧光显微镜获得的清理后的啮齿动物大脑的三像素级细胞分辨率图像已经改变了我们研究大脑的方式。实现这项技术的潜力需要计算管道,这些计算管道可以在实验协议中进行推广,并在层流和亚种群特定水平上绘制神经活动图,超出atlas定义的区域。在这里,我们提出了基于人工智能的集成制图(ACE),这是一种端到端管道,采用三维深度学习分割模型和先进的聚类统计算法,以实现局部神经元活动和连接的无偏映射。针对最先进的分割和检测方法在未见数据集上的验证证明了ACE的高泛化性和性能。在两种不同的神经生物学背景下应用ACE,我们发现了现有的基于图谱的分析所遗漏的分区域效应,并展示了ACE揭示全脑局部或层状神经元活动的能力。我们的开源管道能够在广泛的神经科学应用中以高精确度对神经元集合进行全脑映射。
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来源期刊
Nature Methods
Nature Methods 生物-生化研究方法
CiteScore
58.70
自引率
1.70%
发文量
326
审稿时长
1 months
期刊介绍: Nature Methods is a monthly journal that focuses on publishing innovative methods and substantial enhancements to fundamental life sciences research techniques. Geared towards a diverse, interdisciplinary readership of researchers in academia and industry engaged in laboratory work, the journal offers new tools for research and emphasizes the immediate practical significance of the featured work. It publishes primary research papers and reviews recent technical and methodological advancements, with a particular interest in primary methods papers relevant to the biological and biomedical sciences. This includes methods rooted in chemistry with practical applications for studying biological problems.
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