Approach to machine learning for extraction of real-world data variables from electronic health records

Blythe Adamson; Michael Waskom; Auriane Blarre; Jonathan Kelly; Konstantin Krismer; Sheila Nemeth; James Gippetti; John Ritten; Katherine Harrison; George Ho; Robin Linzmayer; Tarun Bansal; Samuel Wilkinson; Guy Amster; Evan Estola; Corey M Benedum; Erin Fidyk; Melissa Estévez; Will Shapiro; Aaron B Cohen

doi:10.3389/fphar.2023.1180962

Approach to machine learning for extraction of real-world data variables from electronic health records

Front Pharmacol. 2023 Sep 15:14:1180962. doi: 10.3389/fphar.2023.1180962. eCollection 2023.

Authors

Blythe Adamson^{1

2}, Michael Waskom¹, Auriane Blarre¹, Jonathan Kelly¹, Konstantin Krismer¹, Sheila Nemeth¹, James Gippetti¹, John Ritten¹, Katherine Harrison¹, George Ho¹, Robin Linzmayer¹, Tarun Bansal¹, Samuel Wilkinson¹, Guy Amster¹, Evan Estola¹, Corey M Benedum¹, Erin Fidyk¹, Melissa Estévez¹, Will Shapiro¹, Aaron B Cohen^{1

3}

Affiliations

¹ Flatiron Health, Inc., New York, NY, United States.
² The Comparative Health Outcomes, Policy, and Economics (CHOICE) Institute, Department of Pharmacy, University of Washington, Seattle, WA, United States.
³ Department of Medicine, NYU Grossman School of Medicine, New York, NY, United States.

Abstract

Background: As artificial intelligence (AI) continues to advance with breakthroughs in natural language processing (NLP) and machine learning (ML), such as the development of models like OpenAI's ChatGPT, new opportunities are emerging for efficient curation of electronic health records (EHR) into real-world data (RWD) for evidence generation in oncology. Our objective is to describe the research and development of industry methods to promote transparency and explainability. Methods: We applied NLP with ML techniques to train, validate, and test the extraction of information from unstructured documents (e.g., clinician notes, radiology reports, lab reports, etc.) to output a set of structured variables required for RWD analysis. This research used a nationwide electronic health record (EHR)-derived database. Models were selected based on performance. Variables curated with an approach using ML extraction are those where the value is determined solely based on an ML model (i.e. not confirmed by abstraction), which identifies key information from visit notes and documents. These models do not predict future events or infer missing information. Results: We developed an approach using NLP and ML for extraction of clinically meaningful information from unstructured EHR documents and found high performance of output variables compared with variables curated by manually abstracted data. These extraction methods resulted in research-ready variables including initial cancer diagnosis with date, advanced/metastatic diagnosis with date, disease stage, histology, smoking status, surgery status with date, biomarker test results with dates, and oral treatments with dates. Conclusion: NLP and ML enable the extraction of retrospective clinical data in EHR with speed and scalability to help researchers learn from the experience of every person with cancer.

Keywords: artificial intelligence; cancer; electronic health records; machine learning; natural language processing; oncology; real-world data.

Grants and funding

This study received funding from Flatiron Health. The funder was involved in the study design, collection, analysis, interpretation of data, the writing of this article or the decision to submit it for publication.