Detection of Infectious Symptoms from VA Emergency Department and Primary Care Clinical Documentation

Overview

Journal Int J Med Inform

Specialty Medical Informatics

Date 2012 Jan 17

PMID 22244191

Citations 17

Authors

Michael E Matheny

Fern FitzHenry

Theodore Speroff

Jennifer K Green

Michelle L Griffith

Eduard E Vasilevskis

Elliot M Fielstein

Peter L Elkin

Steven H Brown

Affiliations

Soon will be listed here.

Abstract

Objective: The majority of clinical symptoms are stored as free text in the clinical record, and this information can inform clinical decision support and automated surveillance efforts if it can be accurately processed into computer interpretable data.

Methods: We developed rule-based algorithms and evaluated a natural language processing (NLP) system for infectious symptom detection using clinical narratives. Training (60) and testing (444) documents were randomly selected from VA emergency department, urgent care, and primary care records. Each document was processed with NLP and independently manually reviewed by two clinicians with adjudication by referee. Infectious symptom detection rules were developed in the training set using keywords and SNOMED-CT concepts, and subsequently evaluated using the testing set.

Results: Overall symptom detection performance was measured with a precision of 0.91, a recall of 0.84, and an F measure of 0.87. Overall symptom detection with assertion performance was measured with a precision of 0.67, a recall of 0.62, and an F measure of 0.64. Among those instances in which the automated system matched the reference set determination for symptom, the system correctly detected 84.7% of positive assertions, 75.1% of negative assertions, and 0.7% of uncertain assertions.

Conclusion: This work demonstrates how processed text could enable detection of non-specific symptom clusters for use in automated surveillance activities.

Citing Articles

Identifying Symptoms Prior to Pancreatic Ductal Adenocarcinoma Diagnosis in Real-World Care Settings: Natural Language Processing Approach.

Xie F, Chang J, Luong T, Wu B, Lustigova E, Shrader E JMIR AI. 2024; 3:e51240.

PMID: 38875566 PMC: 11041417. DOI: 10.2196/51240.

Combining text mining with clinical decision support in clinical practice: a scoping review.

van de Burgt B, Wasylewicz A, Dullemond B, Grouls R, Egberts T, Bouwman A J Am Med Inform Assoc. 2022; 30(3):588-603.

PMID: 36512578 PMC: 9933076. DOI: 10.1093/jamia/ocac240.

Extraction and Quantification of Words Representing Degrees of Diseases: Combining the Fuzzy C-Means Method and Gaussian Membership.

Han F, Zhang Z, Zhang H, Nakaya J, Kudo K, Ogasawara K JMIR Form Res. 2022; 6(11):e38677.

PMID: 36399376 PMC: 9719062. DOI: 10.2196/38677.

Sepsis prediction, early detection, and identification using clinical text for machine learning: a systematic review.

Yan M, Gustad L, Nytro O J Am Med Inform Assoc. 2021; 29(3):559-575.

PMID: 34897469 PMC: 8800516. DOI: 10.1093/jamia/ocab236.

Use of the Systematized Nomenclature of Medicine Clinical Terms (SNOMED CT) for Processing Free Text in Health Care: Systematic Scoping Review.

Gaudet-Blavignac C, Foufi V, Bjelogrlic M, Lovis C J Med Internet Res. 2021; 23(1):e24594.

PMID: 33496673 PMC: 7872838. DOI: 10.2196/24594.