On Image Quality Metadata, FAIR in ML, AI-Readiness and Reproducibility: Fish-AIR example

Y. Bakiş, Xiaojun Wang, B. Altıntaş, Dom Jebbia, Henry Bart Jr.
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引用次数: 0

Abstract

A new science discipline has emerged within the last decade at the intersection of informatics, computer science and biology: Imageomics. Like most other -omics fields, Imageomics also uses emerging technologies to analyze biological data but from the images. One of the most applied data analysis methods for image datasets is Machine Learning (ML). In 2019, we started working on a United States National Science Foundation (NSF) funded project, known as Biology Guided Neural Networks (BGNN) with the purpose of extracting information about biology by using neural networks and biological guidance such as species descriptions, identifications, phylogenetic trees and morphological annotations (Bart et al. 2021). Even though the variety and abundance of biological data is satisfactory for some ML analysis and the data are openly accessible, researchers still spend up to 80% of their time preparing data into a usable, AI-ready format, leaving only 20% for exploration and modeling (Long and Romanoff 2023). For this reason, we have built a dataset composed of digitized fish specimens, taken either directly from collections or from specialized repositories. The range of digital representations we cover is broad and growing, from photographs and radiographs, to CT scans, and even illustrations. We have added new groups of vocabularies to the dataset management system including image quality metadata, extended image metadata and batch metadata. With the image quality metadata and extended image metadata, we aimed to extract information from the digital objects that can possibly help ML scientists in their research with filtering, image processing and object recognition routines. Image quality metadata provides information about objects contained in the image, features and condition of the specimen, and some basic visual properties of the image, while extended image metadata provides information about technical properties of the digital file and the digital multimedia object (Bakış et al. 2021, Karnani et al. 2022, Leipzig et al. 2021, Pepper et al. 2021, Wang et al. 2021) (see details on Fish-AIR vocabulary web page). Batch metadata is used for separating different datasets and facilitates downloading and uploading data in batches with additional batch information and supplementary files. Additional flexibility, built into the database infrastructure using an RDF framework, will enable the system to host different taxonomic groups, which might require new metadata features (Jebbia et al. 2023). By the combination of these features, along with FAIR (Findable, Accessable, Interoperable, Reusable) principles, and reproducibility, we provide Artificial Intelligence Readiness (AIR; Long and Romanoff 2023) to the dataset. Fish-AIR provides an easy-to-access, filtered, annotated and cleaned biological dataset for researchers from different backgrounds and facilitates the integration of biological knowledge based on digitized preserved specimens into ML pipelines. Because of the flexible database infrastructure and addition of new datasets, researchers will also be able to access additional types of data—such as landmarks, specimen outlines, annotated parts, and quality scores—in the near future. Already, the dataset is the largest and most detailed AI-ready fish image dataset with integrated Image Quality Management System (Jebbia et al. 2023, Wang et al. 2021).
关于图像质量元数据,机器学习中的公平,人工智能的准备和可重复性:Fish-AIR示例
在过去十年中,在信息学、计算机科学和生物学的交叉领域出现了一门新的科学学科:图像组学。像大多数其他组学领域一样,图像组学也使用新兴技术来分析生物数据,但只是从图像中。机器学习(ML)是图像数据集最常用的数据分析方法之一。2019年,我们开始在美国国家科学基金会(NSF)资助的项目上工作,该项目被称为生物引导神经网络(BGNN),目的是通过使用神经网络和生物指导,如物种描述、鉴定、系统发育树和形态注释来提取生物学信息(Bart et al. 2021)。尽管生物数据的多样性和丰丰性对一些ML分析来说是令人满意的,而且数据是公开可访问的,但研究人员仍然花费高达80%的时间将数据准备成可用的ai格式,只剩下20%的时间用于探索和建模(Long and Romanoff 2023)。出于这个原因,我们建立了一个由数字化鱼类标本组成的数据集,这些标本要么直接来自收集品,要么来自专门的储存库。我们涵盖的数字表示的范围是广泛的和不断增长的,从照片和x光片,到CT扫描,甚至插图。我们在数据集管理系统中添加了新的词汇组,包括图像质量元数据、扩展图像元数据和批处理元数据。通过图像质量元数据和扩展图像元数据,我们旨在从数字对象中提取信息,这些信息可能有助于ML科学家进行过滤,图像处理和对象识别例程的研究。图像质量元数据提供有关图像中包含的对象、样本的特征和状态以及图像的一些基本视觉属性的信息,而扩展图像元数据提供有关数字文件和数字多媒体对象的技术属性的信息(Bakış et al. 2021, Karnani et al. 2022, Leipzig et al. 2021, Pepper et al. 2021, Wang et al. 2021)(详见Fish-AIR词汇网页)。批元数据用于分离不同的数据集,便于批量下载和上传数据,并附带额外的批信息和补充文件。使用RDF框架内置于数据库基础设施中的额外灵活性将使系统能够托管不同的分类组,这可能需要新的元数据特性(Jebbia et al. 2023)。通过结合这些特性,以及FAIR(可查找、可访问、可互操作、可重用)原则和可重复性,我们提供了人工智能就绪(AIR;Long和Romanoff 2023)的数据集。Fish-AIR为来自不同背景的研究人员提供易于访问,过滤,注释和清洁的生物数据集,并促进基于数字化保存标本的生物知识整合到ML管道中。由于灵活的数据库基础设施和新数据集的添加,在不久的将来,研究人员还将能够访问其他类型的数据,如地标、标本轮廓、注释部分和质量分数。该数据集已经是集成了图像质量管理系统的最大、最详细的人工智能鱼图像数据集(Jebbia et al. 2023, Wang et al. 2021)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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