AI Article Synopsis
- The study focuses on creating a machine learning model to predict the duration of unassisted spontaneous breathing in patients weaning off mechanical ventilation, balancing the need to avoid overworking respiratory muscles.
- The model consists of a classifier for predicting duration increases and regressor models for estimating exact durations and day-to-day differences using clinical data from a specialized weaning unit.
- Although the results show promise, the model's prognostic quality currently falls short for direct clinical application.
Article Abstract
Purpose: Treatment of patients undergoing prolonged weaning from mechanical ventilation includes repeated spontaneous breathing trials (SBTs) without respiratory support, whose duration must be balanced critically to prevent over- and underload of respiratory musculature. This study aimed to develop a machine learning model to predict the duration of unassisted spontaneous breathing.
Materials And Methods: Structured clinical data of patients from a specialized weaning unit were used to develop (1) a classifier model to qualitatively predict an increase of duration, (2) a regressor model to quantitatively predict the precise duration of SBTs on the next day, and (3) the duration difference between the current and following day. 61 features, known to influence weaning, were included into a Histogram-based gradient boosting model. The models were trained and evaluated using separated data sets.
Results: 18.948 patient-days from 1018 individual patients were included. The classifier model yielded an ROC-AUC of 0.713. The regressor models displayed a mean absolute error of 2:50 h for prediction of absolute durations and 2:47 h for day-to-day difference.
Conclusions: The developed machine learning model showed informed results when predicting the spontaneous breathing capacity of a patient in prolonged weaning, however lacking prognostic quality required for direct translation to clinical use.
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| http://dx.doi.org/10.1016/j.jcrc.2024.154795 | DOI Listing |
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