Partitioning into training and testing sets.

Partitioning into training and testing sets.

<div><p>Objectives</p><p>Accurately predicting the mortality risk of hypothermia patients is crucial for clinical decision-making, offering ample time for physicians to intervene. However, existing methods are invasive and difficult to implement in pre-hospital settings.</...

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Bibliographic Details
Main Author: Chunliang Jiang (22477803) (author)
Other Authors: GuoFeng Ru (22477806) (author), GuanJun Liu (22477809) (author), Huiquan Wang (13762) (author), Xin Ma (37268) (author), JiaMeng Xu (22477812) (author), YiJing Fu (22477815) (author), Jing Yuan (217967) (author), Guang Zhang (766712) (author)
Published: 2025
Subjects:
Medicine
Developmental Biology
Cancer
Infectious Diseases
Biological Sciences not elsewhere classified
Mathematical Sciences not elsewhere classified
Information Systems not elsewhere classified
offering ample time
machine learning method
machine learning approach
840 &# 8211
minimal feature subsets
entire feature subset
offer decision support
mortality prediction method
comprising 360 non
auc values increased
mortality prediction model
hypothermia patients based
700 hypothermia patients
invasive physiological parameters
hypothermia patients
temperature feature
model training
invasive parameters
hypothermic patients
clinical decision
predicting mortality
mortality risk
hour mortality
xlink ">
xgboost models
vital importance
using non
remote areas
predicting 72
overall features
existing methods
disaster sites
demonstrating robustness
center validation
125 hospitals
122 hospitals
039 compared
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Summary:<div><p>Objectives</p><p>Accurately predicting the mortality risk of hypothermia patients is crucial for clinical decision-making, offering ample time for physicians to intervene. However, existing methods are invasive and difficult to implement in pre-hospital settings.</p><p>Methods</p><p>In this study, records of 2,700 hypothermia patients from 125 hospitals were extracted from the eICU Collaborative Research database, comprising 360 non-survivors and 2,340 survivors. Four machine learning methods were utilized to develop a mortality prediction model for hypothermia patients based on non-invasive physiological parameters. Data from 122 hospitals were used for model training, while the remainder were utilized for performance validation.</p><p>Results</p><p>The proposed machine learning prediction model achieved an area under the receiver operating characteristic curve (AUC) of 0.869 (95%CI: 0.840–0.895), demonstrating good mortality predictive performance for hypothermia patients only using non-invasive physiological parameters. Optimal and minimal feature subsets were selected for each machine learning method. The optimal feature subsets contained only 70.6% of the overall features for XGBoost models, while the AUC values increased by 0.039 compared to that of the entire feature subset. The interpretability analysis results highlight the vital importance of the temperature feature in predicting mortality during episodes of hypothermia in patients.</p><p>Conclusions</p><p>This study developed a mortality prediction method for hypothermia patients only using non-invasive parameters, demonstrating robustness and reliability during multi-center validation. It can offer decision support for remote areas and disaster sites where it is difficult to access invasive parameters.</p></div>

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