Applying Machine Learning to Consumer Wearable Data for the Early Detection of Complications After Pediatric Appendectomy

Overview

Journal NPJ Digit Med

Specialty Medical Informatics

Date 2023 Aug 16

PMID 37587211

Authors

Hassan M K Ghomrawi

Megan K OBrien

Michela Carter

Rebecca Macaluso

Rushmin Khazanchi

Michael Fanton

Christopher DeBoer

Samuel C Linton

Suhail Zeineddin

J Benjamin Pitt

Megan Bouchard

Angie Figueroa

Soyang Kwon

Jane L Holl

Arun Jayaraman

Fizan Abdullah

Affiliations

Soon will be listed here.

Abstract

When children are discharged from the hospital after surgery, their caregivers often rely on subjective assessments (e.g., appetite, fatigue) to monitor postoperative recovery as objective assessment tools are scarce at home. Such imprecise and one-dimensional evaluations can result in unwarranted emergency department visits or delayed care. To address this gap in postoperative monitoring, we evaluated the ability of a consumer-grade wearable device, Fitbit, which records multimodal data about daily physical activity, heart rate, and sleep, in detecting abnormal recovery early in children recovering after appendectomy. One hundred and sixty-two children, ages 3-17 years old, who underwent an appendectomy (86 complicated and 76 simple cases of appendicitis) wore a Fitbit device on their wrist for 21 days postoperatively. Abnormal recovery events (i.e., abnormal symptoms or confirmed postoperative complications) that arose during this period were gathered from medical records and patient reports. Fitbit-derived measures, as well as demographic and clinical characteristics, were used to train machine learning models to retrospectively detect abnormal recovery in the two days leading up to the event for patients with complicated and simple appendicitis. A balanced random forest classifier accurately detected 83% of these abnormal recovery days in complicated appendicitis and 70% of abnormal recovery days in simple appendicitis prior to the true report of a symptom/complication. These results support the development of machine learning algorithms to predict onset of abnormal symptoms and complications in children undergoing surgery, and the use of consumer wearables as monitoring tools for early detection of postoperative events.

Citing Articles

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