A PROSPECTIVE CLINICAL STUDY ON THE USE OF A NON-INVASIVE WEARABLE DEVICE AND NEURAL NETWORK MODELS FOR PATIENTS WITH DENGUE

Journal article

Intro: Dengue epidemics impose considerable strain on healthcare resources. Real-time continuous and non-invasive monitoring of patients admitted to the hospital could lead to improved care and outcomes. We evaluated the performance of a commercially-available wearable (SmartCare) utilising photoplethysmography (PPG) to stratify clinical risk for a cohort of hospitalised dengue patients in Vietnam. Methods: We performed a prospective observational study for adult and paediatric patients with a clinical diagnosis of dengue at the Hospital for Tropical Disease, Ho Chi Minh City, Vietnam. Patients underwent PPG monitoring early during admission alongside standard clinical care. PPG waveforms were analysed using machine learning models. Adult patients were classified into 3 severity classes: i) uncomplicated (ward-based), ii) moderate - severe (ED-based), and iii) severe (ICU-based). Data from paediatric patients were split into 2 classes: i) severe (during ICU stay) and ii) follow-up (7-14 days after discharge). Model performances were evaluated using standard classification metrics and 5-fold stratified cross-validation. Findings: We included PPG and clinical data from 132 adults and 15 children with a median age of 28 and 12 years respectively. 1781 hours of PPG data were available for analysis. The best performing convolutional neural network model (CNN) achieved a precision of 0.785 and recall of 0.771 in classifying adult patients according to severity class and precision of 0.891 and recall of 0.891 in classifying between disease and post-disease state in paediatric patients. Conclusion: We demonstrate that use of a low-cost wearable provided clinically actionable data to differentiate between patients with dengue of varying severity. Continuous monitoring and connectivity to early warning systems could provide significant benefits to clinical care in dengue, particularly within an endemic setting. Work is currently underway to implement these models for dynamic risk predictions and provide individualised patient care.

Authors: Karolcik, S; Manginas, V; Ho, C; Daniels, J; Nguyen, G

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: Elsevier
• Journal: International Journal of Infectious Diseases
• Volume: 130
• Pages: S4-S4
• Publication date: 2023-05-01
• DOI: 10.1016/j.ijid.2023.04.017
• EISSN: 1878-3511
• ISSN: 1201-9712
• Language: English
• Keywords: Wearable computer; Virology; Computer science; Artificial neural network; Artificial intelligence; Medicine; Dengue fever; Embedded system