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Electronic-Medical-Record-Driven Machine Learning Predictive Model for Hospital-Acquired Pressure Injuries:

Kim-Anh-Nhi Nguyen1, Dhavalkumar Patel1, Masoud Edalati1

  • 1Institute for Healthcare Delivery Science, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA.

Journal of Clinical Medicine
|February 26, 2025
PubMed
Summary
This summary is machine-generated.

A new machine learning model accurately predicts hospital-acquired pressure injuries (HAPIs) using electronic medical record data. This advanced tool improves upon existing methods for better patient care and prevention.

Keywords:
automated EMR integrationclinical decision supportelectronic medical recordsexternal validationhospital-acquired pressure injurymachine learningmulti-center validationpredictive modelpressure ulcerwound care management

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Area of Science:

  • Bioengineering
  • Health Informatics
  • Clinical Prediction Models

Background:

  • Hospital-acquired pressure injuries (HAPIs) impact millions of patients annually in the US, increasing morbidity and healthcare expenses.
  • Existing screening tools like the Braden Scale exhibit limitations in sensitivity for accurate HAPI risk assessment.
  • There is a critical need for enhanced predictive methodologies to mitigate HAPI incidence.

Purpose of the Study:

  • To develop and validate a machine learning (ML) model for predicting HAPI risk.
  • To leverage longitudinal electronic medical record (EMR) data for dynamic risk assessment.
  • To establish a generalizable and scalable model for cross-institutional application.

Main Methods:

  • Development of an automated pipeline for EMR data curation, labeling, and integration.
  • Utilized XGBoost with recursive feature elimination to identify 35 key clinical variables.
  • Employed time-series analysis for dynamic HAPI risk prediction in adult inpatients (2018-2023).

Main Results:

  • The ML model achieved strong performance with AUROC values of 0.83-0.85 during internal and multi-center external validation.
  • The model demonstrated superior sensitivity and F1-score compared to the Braden Scale.
  • Performance surpassed previous predictive models for HAPI risk.

Conclusions:

  • This study presents the first externally validated, cross-institutional HAPI prediction model utilizing longitudinal EMR data and automated pipelines.
  • The model exhibits significant generalizability, scalability, and real-time applicability for clinical settings.
  • This bioengineering approach offers a novel strategy to enhance HAPI prevention, patient outcomes, and operational efficiency.