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An Automatic and End-to-End System for Rare Disease Knowledge Graph Construction Based on Ontology-Enhanced Large

Lang Cao1, Jimeng Sun1, Adam Cross2

  • 1Department of Computer Science, University of Illinois Urbana-Champaign, Urbana, IL, United States.

JMIR Medical Informatics
|December 18, 2024
PubMed
Summary
This summary is machine-generated.

Automated rare disease mining (AutoRD) improves rare disease identification from medical text by integrating large language models with ontologies. This system enhances patient identification for research and clinical trials, overcoming limitations of current methods.

Keywords:
clinical informaticsLLMartificial intelligencedata extractionknowledge graphslarge language modelsmachine learningnatural language processingontologiesrare diseasetext mining

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Area of Science:

  • Biomedical Informatics
  • Natural Language Processing
  • Rare Disease Research

Background:

  • Rare diseases affect millions globally but lack specific diagnostic codes (ICD-9, ICD-10), hindering patient identification and research.
  • Current large language models (LLMs) lack specialized medical knowledge for effective rare disease data management and extraction.
  • Challenges in rare disease identification complicate clinical trial recruitment and research efforts.

Purpose of the Study:

  • To develop an automated system (AutoRD) for extracting rare disease information from medical text.
  • To integrate ontologies and structured knowledge for superior rare disease entity and relation extraction.
  • To surpass the performance of common LLMs and traditional methods in rare disease mining.

Main Methods:

  • Developed AutoRD as a pipeline: data preprocessing, entity/relation extraction, entity calibration, and knowledge graph construction.
  • Utilized GPT-4 and medical knowledge graphs from Human Phenotype and Orphanet ontologies.
  • Employed chain-of-thought reasoning and prompt engineering for enhanced extraction.

Main Results:

  • AutoRD achieved an overall entity extraction F1-score of 56.1% and relation extraction F1-score of 38.6% on the RareDis2023 dataset.
  • Demonstrated a 14.4% improvement over baseline LLMs in overall extraction performance.
  • Achieved a high F1-score of 83.5% for rare disease entity extraction, showcasing precision and recall.

Conclusions:

  • AutoRD effectively extracts rare disease information and builds knowledge graphs, addressing LLM limitations in this domain.
  • Ontology-enhanced LLMs significantly improve rare disease identification and connection to clinical features.
  • The system facilitates better patient identification for research and clinical trial recruitment, promoting inclusivity.