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A Metadata Extraction Approach for Clinical Case Reports to Enable Advanced Understanding of Biomedical Concepts
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Application of a Natural Language Processing Framework for Data Extraction From Pathology Reports Across Multiple

Phillip Park1,2, Yeonho Choi2, Nayoung Han3

  • 1Department of Digital Health, Samsung Advanced Institute for Health Sciences and Technology, Sungkyunkwan University, Seoul, Korea.

Journal of Korean Medical Science
|March 3, 2026
PubMed
Summary
This summary is machine-generated.

This study demonstrates how natural language processing (NLP) systems, particularly ClinicalBERT, can automate data extraction from pathology reports. This improves the efficiency and accuracy of clinical data analysis for various cancer types.

Keywords:
CancerDatabaseNatural Language ProcessingPathology Report

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Area of Science:

  • Computational biology
  • Medical informatics
  • Natural Language Processing

Background:

  • Pathology reports contain valuable clinical and pathological data but are challenging to extract for research.
  • An efficient natural language processing (NLP) system was developed to automate data extraction from semi-structured pathology reports.
  • The system facilitates streamlined storage, retrieval, and analysis of clinical data in a centralized database.

Purpose of the Study:

  • To develop and evaluate an automated system for extracting clinical data from pathology reports.
  • To compare the performance of different deep learning models for this NLP task.
  • To identify the optimal model for accurate and efficient data extraction.

Main Methods:

  • Comparative analysis of deep learning architectures including LSTM, CNN, and transformer-based models (BERT, BioBERT, ClinicalBERT).
  • Evaluation of model performance based on accuracy and efficiency in extracting variables from pathology reports.
  • Selection of ClinicalBERT as the base model due to its proficiency in medical terminology and context.

Main Results:

  • ClinicalBERT demonstrated superior performance in classifying variables across multiple cancer types.
  • High F1 scores (≥0.99) were achieved for most variables in liver cancer.
  • Variable performance was observed for other cancers, with some achieving perfect scores (F1=1.0) and others requiring further optimization (e.g., distant metastasis in stomach cancer).

Conclusions:

  • NLP systems, specifically ClinicalBERT, are effective in automating the extraction of clinical data from pathology reports.
  • This automated approach simplifies data processing and enhances the accuracy of extracted information.
  • The developed system shows promise for improving cancer research through efficient data utilization.