光学神经图像工作室(OptiNiSt):直观、可扩展的光学神经图像数据分析框架

Yukako Yamane, Yuzhe Li, Keita Matsumoto, Ryota Kanai, Miles Desforges, Carlos Enrique Gutierrez, Kenji Doya
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摘要

钙离子指示剂和光学技术的进步已使光学神经记录成为神经科学的常用工具。随着光学神经记录数据量的增长,简化图像预处理、信号提取和后续神经活动分析的数据分析管道变得至关重要。光学神经数据分析面临许多挑战。1) 每一步都需要仔细检查原始数据和处理数据的质量。2) 由于图像预处理、细胞提取和活动分析算法众多,各有利弊,实验人员需要实施或安装这些算法,以比较和选择每个处理步骤的最佳方法和参数。3) 为确保研究的可重复性,需要系统地记录每个分析步骤。4) 为了实现数据共享和荟萃分析,需要采用标准数据格式和处理协议。为了应对这些挑战,我们开发了光学神经影像工作室(OptiNiSt)(https://github.com/oist/optinist),这是一个用于直观创建钙数据分析管道的框架,具有可扩展性、可扩展性和可重现性。OptiNiSt 包括以下功能。1)研究人员可以通过选择多个处理模块、调整其参数,并通过网络浏览器中的图形用户界面可视化每一步的结果,从而轻松创建分析管道。2) 除了预装的常用分析工具外,还可以轻松添加新的 Python 分析算法。3) 一旦设计好处理流水线,整个工作流程及其模块和参数都会存储在 YAML 文件中,这使得流水线具有可重复性,并可在高性能计算集群上部署。4) OptiNiSt 可以读取各种文件格式的图像数据,并将分析结果存储在用于数据共享的标准数据格式 NWB(无国界神经数据)中。我们希望这一框架将有助于实现光学神经数据分析协议的标准化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optical Neuroimage Studio (OptiNiSt): intuitive, scalable, extendable framework for optical neuroimage data analysis
Advancements in calcium indicators and optical techniques have made optical neural recording a common tool in neuroscience. As the volume of optical neural recording data grows, streamlining the data analysis pipelines for image preprocessing, signal extraction, and subsequent neural activity analyses becomes essential. There are a number of challenges in optical neural data analysis. 1) The quality of original and processed data needs to be carefully examined at each step. 2) As there are numerous image preprocessing, cell extraction, and activity analysis algorithms, each with pros and cons, experimenters need to implement or install them to compare and select optimal methods and parameters for each step of processing. 3) To ensure the reproducibility of the research, each analysis step needs to be recorded in a systematic way. 4) For data sharing and meta-analyses, adoption of standard data formats and processing protocols is required. To address these challenges, we developed Optical Neuroimage Studio (OptiNiSt) (https://github.com/oist/optinist), a framework for intuitively creating calcium data analysis pipelines that are scalable, extendable, and reproducible. OptiNiSt includes the following features. 1) Researchers can easily create analysis pipelines by selecting multiple processing modules, tuning their parameters, and visualizing the results at each step through a graphic user interface in a web browser. 2) In addition to common analytical tools that are pre-installed, new analysis algorithms in Python can be easily added. 3) Once a processing pipeline is designed, the entire workflow with its modules and parameters are stored in a YAML file, which makes the pipeline reproducible and deployable on high-performance computing clusters. 4) OptiNiSt can read image data in a variety of file formats and store the analysis results in NWB (Neurodata Without Borders), a standard data format for data sharing. We expect that this framework will be helpful in standardizing optical neural data analysis protocols.
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