TY  - JOUR
AU  - Lin, Yu-Ting
AU  - Deng, Yuan-Xiang
AU  - Tsai, Chu-Lin
AU  - Huang, Chien-Hua
AU  - Fu, Li-Chen
PY  - 2024
DA  - 2024/4/1
TI  - Interpretable Deep Learning System for Identifying Critical Patients Through the Prediction of Triage Level, Hospitalization, and Length of Stay: Prospective Study
JO  - JMIR Med Inform
SP  - e48862
VL  - 12
KW  - emergency department
KW  - triage system
KW  - hospital admission
KW  - length of stay
KW  - multimodal integration
AB  - Background: Triage is the process of accurately assessing patients’ symptoms and providing them with proper clinical treatment in the emergency department (ED). While many countries have developed their triage process to stratify patients’ clinical severity and thus distribute medical resources, there are still some limitations of the current triage process. Since the triage level is mainly identified by experienced nurses based on a mix of subjective and objective criteria, mis-triage often occurs in the ED. It can not only cause adverse effects on patients, but also impose an undue burden on the health care delivery system. Objective: Our study aimed to design a prediction system based on triage information, including demographics, vital signs, and chief complaints. The proposed system can not only handle heterogeneous data, including tabular data and free-text data, but also provide interpretability for better acceptance by the ED staff in the hospital. Methods: In this study, we proposed a system comprising 3 subsystems, with each of them handling a single task, including triage level prediction, hospitalization prediction, and length of stay prediction. We used a large amount of retrospective data to pretrain the model, and then, we fine-tuned the model on a prospective data set with a golden label. The proposed deep learning framework was built with TabNet and MacBERT (Chinese version of bidirectional encoder representations from transformers [BERT]). Results: The performance of our proposed model was evaluated on data collected from the National Taiwan University Hospital (901 patients were included). The model achieved promising results on the collected data set, with accuracy values of 63%, 82%, and 71% for triage level prediction, hospitalization prediction, and length of stay prediction, respectively. Conclusions: Our system improved the prediction of 3 different medical outcomes when compared with other machine learning methods. With the pretrained vital sign encoder and repretrained mask language modeling MacBERT encoder, our multimodality model can provide a deeper insight into the characteristics of electronic health records. Additionally, by providing interpretability, we believe that the proposed system can assist nursing staff and physicians in taking appropriate medical decisions. 
SN  - 2291-9694
UR  - https://medinform.jmir.org/2024/1/e48862
UR  - https://doi.org/10.2196/48862
UR  - http://www.ncbi.nlm.nih.gov/pubmed/38557661
DO  - 10.2196/48862
ID  - info:doi/10.2196/48862
ER  -