Nicole K Guittari, Miguel E Wimbish, Patricia K Rivlin, Mark A Hinton, Jordan K Matelsky, Victoria A Rose, Jorge L Rivera, Nicole E Stock, Brock A Wester, Erik C Johnson, William R Gray-Roncal
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引用次数: 0
Abstract
The promise of large-scale, high-resolution datasets from Electron Microscopy (EM) and X-ray Microtomography (XRM) lies in their ability to reveal neural structures and synaptic connectivity, which is critical for understanding the brain. Effectively managing these complex and rapidly increasing datasets will enable new scientific insights, facilitate querying, and support secondary use across the neuroscience community. However, without effective neurodata standards that permit use of these data across multiple systems and workflows, these valuable and costly datasets risk being underutilized especially as they surpass petascale levels. These standards will promote data sharing through accessible interfaces, allow researchers to build on each other's work, and guide the development of tools and capabilities that are interoperable. Herein we outline a standards framework for creating and managing annotations originating and derived from high-resolution volumetric imaging and connectomic datasets, focusing on ensuring Findable, Accessible, Interoperable, and Reusable (FAIR) practices. The goal is to enhance collaborative efforts, boost the reliability of findings, and enable comparative analysis across growing datasets of different species and modalities. We have formed a global working group with academic and industry partners in the high-resolution volumetric data generation and analysis community, focused on identifying gaps in current EM and XRM data pipelines, and refining outlines and platforms for standardizing EM and XRM methods. This focus considers existing and past community approaches and includes examining neuronal entities, biological components, and associated metadata, while emphasizing adaptability and fostering collaboration.
来自电子显微镜(EM)和 X 射线显微层析成像(XRM)的大规模、高分辨率数据集的前景在于其揭示神经结构和突触连接的能力,这对于理解大脑至关重要。有效管理这些复杂且快速增长的数据集将有助于获得新的科学见解、方便查询并支持神经科学界的二次利用。然而,如果没有有效的神经数据标准,允许在多个系统和工作流程中使用这些数据,这些宝贵而昂贵的数据集就有可能得不到充分利用,尤其是当它们超过千万亿次级别时。这些标准将通过可访问的接口促进数据共享,使研究人员能够在彼此工作的基础上开展研究,并指导开发具有互操作性的工具和功能。在此,我们概述了一个标准框架,用于创建和管理源自高分辨率容积成像和连接组学数据集的注释,重点是确保可查找、可访问、可互操作和可重用(FAIR)实践。我们的目标是加强合作,提高研究结果的可靠性,并在不同物种和模式的不断增长的数据集中进行比较分析。我们与高分辨率容积数据生成和分析领域的学术界和产业界合作伙伴成立了一个全球工作组,重点是找出当前 EM 和 XRM 数据管道中的差距,并完善 EM 和 XRM 方法标准化的大纲和平台。这一重点考虑了现有和过去的社区方法,包括检查神经元实体、生物组件和相关元数据,同时强调适应性和促进合作。