Modelling Adverse Events with the TOP Phenotyping Framework.

Q3 Health Professions
Christoph Beger, Anna Maria Boehmer, Beate Mussawy, Louisa Redeker, Franz Matthies, Ralph Schäfermeier, Annette Härdtlein, Tobias Dreischulte, Daniel Neumann, Alexandr Uciteli
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引用次数: 0

Abstract

The detection and prevention of medication-related health risks, such as medication-associated adverse events (AEs), is a major challenge in patient care. A systematic review on the incidence and nature of in-hospital AEs found that 9.2% of hospitalised patients suffer an AE, and approximately 43% of these AEs are considered to be preventable. Adverse events can be identified using algorithms that operate on electronic medical records (EMRs) and research databases. Such algorithms normally consist of structured filter criteria and rules to identify individuals with certain phenotypic traits, thus are referred to as phenotype algorithms. Many attempts have been made to create tools that support the development of algorithms and their application to EMRs. However, there are still gaps in terms of functionalities of such tools, such as standardised representation of algorithms and complex Boolean and temporal logic. In this work, we focus on the AE delirium, an acute brain disorder affecting mental status and attention, thus not trivial to operationalise in EMR data. We use this AE as an example to demonstrate the modelling process in our ontology-based framework (TOP Framework) for modelling and executing phenotype algorithms. The resulting semantically modelled delirium phenotype algorithm is independent of data structure, query languages and other technical aspects, and can be run on a variety of source systems in different institutions.

用TOP表型框架模拟不良事件。
检测和预防药物相关健康风险,如药物相关不良事件(ae),是患者护理的主要挑战。一项关于院内不良事件发生率和性质的系统综述发现,9.2%的住院患者遭受不良事件,其中约43%的不良事件被认为是可以预防的。不良事件可以通过在电子医疗记录(emr)和研究数据库上运行的算法来识别。这种算法通常由结构化的过滤标准和规则组成,以识别具有某些表型特征的个体,因此被称为表型算法。已经进行了许多尝试,以创建支持算法开发及其在电子病历中的应用的工具。然而,在这些工具的功能方面仍然存在差距,例如算法的标准化表示和复杂的布尔逻辑和时间逻辑。在这项工作中,我们专注于AE谵妄,这是一种影响精神状态和注意力的急性脑部疾病,因此在EMR数据中操作并不微不足道。我们使用此AE作为示例来演示基于本体的框架(TOP框架)中建模和执行表型算法的建模过程。由此产生的语义建模谵妄表型算法独立于数据结构、查询语言和其他技术方面,并且可以在不同机构的各种源系统上运行。
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来源期刊
Studies in Health Technology and Informatics
Studies in Health Technology and Informatics Health Professions-Health Information Management
CiteScore
1.20
自引率
0.00%
发文量
1463
期刊介绍: This book series was started in 1990 to promote research conducted under the auspices of the EC programmes’ Advanced Informatics in Medicine (AIM) and Biomedical and Health Research (BHR) bioengineering branch. A driving aspect of international health informatics is that telecommunication technology, rehabilitative technology, intelligent home technology and many other components are moving together and form one integrated world of information and communication media.
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