KG-LIME: predicting individualized risk of adverse drug events for multiple sclerosis disease-modifying therapy.

IF 4.7 2区 医学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS Journal of the American Medical Informatics Association Pub Date : 2024-08-01 DOI:10.1093/jamia/ocae155
Jason Patterson, Nicholas Tatonetti
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Abstract

Objective: The aim of this project was to create time-aware, individual-level risk score models for adverse drug events related to multiple sclerosis disease-modifying therapy and to provide interpretable explanations for model prediction behavior.

Materials and methods: We used temporal sequences of observational medical outcomes partnership common data model (OMOP CDM) concepts derived from an electronic health record as model features. Each concept was assigned an embedding representation that was learned from a graph convolution network trained on a knowledge graph (KG) of OMOP concept relationships. Concept embeddings were fed into long short-term memory networks for 1-year adverse event prediction following drug exposure. Finally, we implemented a novel extension of the local interpretable model agnostic explanation (LIME) method, knowledge graph LIME (KG-LIME) to leverage the KG and explain individual predictions of each model.

Results: For a set of 4859 patients, we found that our model was effective at predicting 32 out of 56 adverse event types (P < .05) when compared to demographics and past diagnosis as variables. We also assessed discrimination in the form of area under the curve (AUC = 0.77 ± 0.15) and area under the precision-recall curve (AUC-PR = 0.31 ± 0.27) and assessed calibration in the form of Brier score (BS = 0.04 ± 0.04). Additionally, KG-LIME generated interpretable literature-validated lists of relevant medical concepts used for prediction.

Discussion and conclusion: Many of our risk models demonstrated high calibration and discrimination for adverse event prediction. Furthermore, our novel KG-LIME method was able to utilize the knowledge graph to highlight concepts that were important to prediction. Future work will be required to further explore the temporal window of adverse event occurrence beyond the generic 1-year window used here, particularly for short-term inpatient adverse events and long-term severe adverse events.

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KG-LIME:预测多发性硬化症改良疗法不良药物事件的个体化风险。
目的:本项目旨在创建与多发性硬化症疾病修饰疗法相关的时间感知、个体水平的药物不良事件风险评分模型,并为模型预测行为提供可解释的解释:该项目的目的是针对与多发性硬化症疾病调整疗法相关的不良药物事件创建时间感知的个人水平风险评分模型,并为模型预测行为提供可解释的解释:我们使用从电子健康记录中提取的观察性医疗结果伙伴关系通用数据模型(OMOP CDM)概念的时间序列作为模型特征。每个概念都有一个嵌入表征,该表征是从在 OMOP 概念关系知识图谱 (KG) 上训练的图卷积网络中学习的。概念嵌入被输入长短期记忆网络,用于预测药物暴露后 1 年的不良事件。最后,我们对局部可解释模型不可知解释(LIME)方法进行了新的扩展,即知识图谱 LIME(KG-LIME),以利用知识图谱并解释每个模型的个别预测:结果:在一组 4859 名患者中,我们发现我们的模型能有效预测 56 种不良事件类型中的 32 种(P 讨论和结论:我们的许多风险模型都显示出较高的预测能力:我们的许多风险模型在不良事件预测方面都表现出了很高的校准性和区分度。此外,我们新颖的 KG-LIME 方法能够利用知识图谱突出对预测很重要的概念。未来的工作将需要进一步探索不良事件发生的时间窗口,而不是这里使用的一般 1 年窗口,尤其是短期住院不良事件和长期严重不良事件。
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来源期刊
Journal of the American Medical Informatics Association
Journal of the American Medical Informatics Association 医学-计算机:跨学科应用
CiteScore
14.50
自引率
7.80%
发文量
230
审稿时长
3-8 weeks
期刊介绍: JAMIA is AMIA''s premier peer-reviewed journal for biomedical and health informatics. Covering the full spectrum of activities in the field, JAMIA includes informatics articles in the areas of clinical care, clinical research, translational science, implementation science, imaging, education, consumer health, public health, and policy. JAMIA''s articles describe innovative informatics research and systems that help to advance biomedical science and to promote health. Case reports, perspectives and reviews also help readers stay connected with the most important informatics developments in implementation, policy and education.
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