Department of Molecular Microbiology and Immunology, Johns Hopkins Bloomberg School of Public Health, Baltimore, Maryland, USA.
mSystems. 2024 Jan 23;9(1):e0065223. doi: 10.1128/msystems.00652-23. Epub 2023 Dec 6.
Scientific research output has increased exponentially over the past few decades, but not equally across all fields of study, and we lack clear methods for estimating the size of any given field of research. Understanding how fields grow, change, and are organized is essential to understanding how human resources are allocated to the investigation of scientific problems. In this study, we estimated the size of certain biomedical fields from the number of unique author names appearing in field-relevant publications in the PubMed database. Focusing on microbiology, where the size of fields is often associated with those who work on a particular microbe, we find large differences in the size of its subfields. We found that plotting the number of unique investigators as a function of time can show changes consistent with growing or shrinking fields. In general, the number of unique author names associated with a particular microbe correlated with the number of disease cases attributed to that microbe, suggesting that the microbiology field workforce is deployed in a manner consistent with the medical importance of the microbe in question. We propose that unique author counts can be used to measure the size of the workforce in any given field, analyze the overlap of the workforce between fields, and compare how the workforce correlates to available research funds and the public health burden of a field.IMPORTANCEScience and its individual fields are growing at spectacular rates along with the number of papers being generated each year. However, we lack methods to investigate the size of these fields, many times relying on anecdotal knowledge on which fields are "hot topics" or oversaturated. Thus, we developed a bibliometric method analyzing authorship information from PubMed to estimate the size of fields based on unique author counts. Our major findings are that unique author counts serve as an efficient measurement of the size of a given field. Additionally, the size of a biomedical science field correlates to its public health burden when compared to case numbers. This method allows us to compare growth rates, workforce distribution, and the allocation of resources between fields to understand how scientific fields self-regulate. These insights can, in turn, help guide policymaking, for example, in funding allocation, to ensure fields are not neglected.
过去几十年,科学研究成果呈指数级增长,但并非所有研究领域都均等增长,而且我们缺乏估算特定研究领域规模的明确方法。了解领域如何增长、变化和组织对于理解如何将人力资源分配到科学问题的研究至关重要。在这项研究中,我们根据 PubMed 数据库中与特定领域相关出版物中出现的独特作者数量来估算某些生物医学领域的规模。我们专注于微生物学,因为领域的规模通常与研究特定微生物的人员数量相关,我们发现其子领域的规模存在很大差异。我们发现,将独特研究者数量作为时间的函数绘制,可以显示出与领域增长或收缩一致的变化。总的来说,与特定微生物相关的独特作者数量与归因于该微生物的疾病病例数量相关,这表明微生物学领域的劳动力是根据有关微生物的医学重要性来部署的。我们提出,独特作者计数可用于衡量特定领域的劳动力规模,分析领域之间的劳动力重叠,并比较劳动力与可用研究资金和领域的公共卫生负担之间的相关性。
科学及其各个领域都在以每年生成的论文数量的惊人速度增长。然而,我们缺乏调查这些领域规模的方法,很多时候依赖于关于哪些领域是“热门话题”或过度饱和的轶事知识。因此,我们开发了一种基于 PubMed 中的作者信息进行分析的计量方法,根据独特作者计数来估算领域规模。我们的主要发现是,独特作者计数是衡量特定领域规模的有效指标。此外,与病例数量相比,生物医学科学领域的规模与其公共卫生负担相关。这种方法使我们能够比较增长率、劳动力分布以及领域之间的资源分配,以了解科学领域如何自我调节。这些见解反过来又可以帮助指导决策制定,例如在资金分配方面,以确保不会忽视某些领域。
