Abstract
This paper implements logistic regression models (LRMs) and feature selection for creating a predictive model for recovery form hemorrhagic shock (HS) with resuscitation using blood in the multiple experimental rat animal protocols. A total of 61 animals were studied across multiple HS experiments, which encompassed two different HS protocols and two resuscitation protocols using blood stored for short periods using five different techniques. Twenty-seven different systemic hemodynamics, cardiac function, and blood gas parameters were measured in each experiment, of which feature selection deemed only 25% of the them as relevant. The reduced feature set was used to train a final logistic regression model. A final test set accuracy is 84% compared to 74% for a baseline classifier using only MAP and HR measurements. Receiver operating characteristics (ROC) curve analysis and Cohens kappa statistics were also used as measures of performance, with the final reduced model outperforming the model, including all parameters. Our results suggest that LRMs trained with a combination of systemic hemodynamics, cardiac function, and blood gas parameters measured at multiple timepoints during HS can successfully classify HS recovery groups. Our results show the predictive ability of traditional and novel hemodynamic and cardiac function features and their combinations, many of which had not previously been taken into consideration, for monitoring HS. Furthermore, we have devised an effective methodology for feature selection and shown ways in which the performance of such predictive models should be assessed in future studies.
Highlights
Trauma remains a major source of morbidity and mortality in the United States and world-wide
Animals were excluded from the logistic regression models (LRMs) if cardiac function data was not collected (n = 1)
In approximately 38% of the animals (23 out of 61) the resuscitation required more than 50% of the original blood volume to recover
Summary
Trauma remains a major source of morbidity and mortality in the United States and world-wide. The World Health Organization estimates that over 5.8 million people die each year because of injuries. This accounts for 10% of the world’s deaths, 32% more than the number of fatalities that result from malaria, tuberculosis and HIV/AIDS combined [1]. Early and accurate assessment of shock state is necessary to provide appropriate interventions to decrease morbidity and mortality. Resuscitation includes control of bleeding, restoration of circulating blood volume, blood pressure, and restitution of oxygen carrying capacity. Significant improvements in HR and MAP may occur during resuscitation such that the indices approach ‘‘normal’’ limits, but the organism in shock may have persistent hypoperfusion. Inadequate resuscitation with persistent hypoperfusion can result in higher mortality rates from HR
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