Mapping vaccine names in clinical trials to vaccine ontology using cascaded fine-tuned domain-specific language models.

IF 1.6 3区 工程技术 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY Journal of Biomedical Semantics Pub Date : 2024-08-10 DOI:10.1186/s13326-024-00318-x
Jianfu Li, Yiming Li, Yuanyi Pan, Jinjing Guo, Zenan Sun, Fang Li, Yongqun He, Cui Tao
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Abstract

Background: Vaccines have revolutionized public health by providing protection against infectious diseases. They stimulate the immune system and generate memory cells to defend against targeted diseases. Clinical trials evaluate vaccine performance, including dosage, administration routes, and potential side effects.

Clinicaltrials: gov is a valuable repository of clinical trial information, but the vaccine data in them lacks standardization, leading to challenges in automatic concept mapping, vaccine-related knowledge development, evidence-based decision-making, and vaccine surveillance.

Results: In this study, we developed a cascaded framework that capitalized on multiple domain knowledge sources, including clinical trials, the Unified Medical Language System (UMLS), and the Vaccine Ontology (VO), to enhance the performance of domain-specific language models for automated mapping of VO from clinical trials. The Vaccine Ontology (VO) is a community-based ontology that was developed to promote vaccine data standardization, integration, and computer-assisted reasoning. Our methodology involved extracting and annotating data from various sources. We then performed pre-training on the PubMedBERT model, leading to the development of CTPubMedBERT. Subsequently, we enhanced CTPubMedBERT by incorporating SAPBERT, which was pretrained using the UMLS, resulting in CTPubMedBERT + SAPBERT. Further refinement was accomplished through fine-tuning using the Vaccine Ontology corpus and vaccine data from clinical trials, yielding the CTPubMedBERT + SAPBERT + VO model. Finally, we utilized a collection of pre-trained models, along with the weighted rule-based ensemble approach, to normalize the vaccine corpus and improve the accuracy of the process. The ranking process in concept normalization involves prioritizing and ordering potential concepts to identify the most suitable match for a given context. We conducted a ranking of the Top 10 concepts, and our experimental results demonstrate that our proposed cascaded framework consistently outperformed existing effective baselines on vaccine mapping, achieving 71.8% on top 1 candidate's accuracy and 90.0% on top 10 candidate's accuracy.

Conclusion: This study provides a detailed insight into a cascaded framework of fine-tuned domain-specific language models improving mapping of VO from clinical trials. By effectively leveraging domain-specific information and applying weighted rule-based ensembles of different pre-trained BERT models, our framework can significantly enhance the mapping of VO from clinical trials.

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使用级联微调特定领域语言模型将临床试验中的疫苗名称映射到疫苗本体。
背景:疫苗通过提供对传染病的保护,彻底改变了公共卫生。疫苗能刺激免疫系统并产生记忆细胞,从而抵御目标疾病。临床试验评估疫苗的性能,包括剂量、给药途径和潜在的副作用。Clinicaltrials: gov 是一个宝贵的临床试验信息库,但其中的疫苗数据缺乏标准化,导致在自动概念映射、疫苗相关知识开发、循证决策和疫苗监控方面面临挑战:在这项研究中,我们开发了一个级联框架,利用多个领域知识源,包括临床试验、统一医学语言系统(UMLS)和疫苗本体(VO),来提高特定领域语言模型的性能,以便自动映射临床试验中的疫苗本体。疫苗本体(VO)是一个基于社区的本体,旨在促进疫苗数据的标准化、集成和计算机辅助推理。我们的方法包括从各种来源中提取和注释数据。然后,我们对 PubMedBERT 模型进行了预训练,最终开发出 CTPubMedBERT。随后,我们将使用 UMLS 进行预训练的 SAPBERT 纳入 CTPubMedBERT,从而增强了 CTPubMedBERT+SAPBERT。通过使用疫苗本体语料库和来自临床试验的疫苗数据进行微调,进一步完善了 CTPubMedBERT + SAPBERT + VO 模型。最后,我们利用一组预先训练好的模型和基于加权规则的集合方法,对疫苗语料库进行了归一化处理,提高了处理的准确性。概念规范化的排序过程包括对潜在概念进行优先排序和排序,以确定最适合特定语境的匹配概念。我们对前 10 个概念进行了排序,实验结果表明,我们提出的级联框架在疫苗映射方面一直优于现有的有效基线,前 1 个候选概念的准确率达到 71.8%,前 10 个候选概念的准确率达到 90.0%:本研究详细介绍了微调特定领域语言模型的级联框架,该框架可改善临床试验中疫苗的映射。通过有效利用特定领域的信息和应用不同预训练 BERT 模型的基于规则的加权集合,我们的框架可以显著提高临床试验中 VO 的映射能力。
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来源期刊
Journal of Biomedical Semantics
Journal of Biomedical Semantics MATHEMATICAL & COMPUTATIONAL BIOLOGY-
CiteScore
4.20
自引率
5.30%
发文量
28
审稿时长
30 weeks
期刊介绍: Journal of Biomedical Semantics addresses issues of semantic enrichment and semantic processing in the biomedical domain. The scope of the journal covers two main areas: Infrastructure for biomedical semantics: focusing on semantic resources and repositories, meta-data management and resource description, knowledge representation and semantic frameworks, the Biomedical Semantic Web, and semantic interoperability. Semantic mining, annotation, and analysis: focusing on approaches and applications of semantic resources; and tools for investigation, reasoning, prediction, and discoveries in biomedicine.
期刊最新文献
Dynamic Retrieval Augmented Generation of Ontologies using Artificial Intelligence (DRAGON-AI). MeSH2Matrix: combining MeSH keywords and machine learning for biomedical relation classification based on PubMed. Annotation of epilepsy clinic letters for natural language processing An extensible and unifying approach to retrospective clinical data modeling: the BrainTeaser Ontology. Concretizing plan specifications as realizables within the OBO foundry.
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