Abstract
BackgroundTimely recognition of hemodynamic instability in critically ill patients enables increased vigilance and early treatment opportunities. We develop the Hemodynamic Stability Index (HSI), which highlights situational awareness of possible hemodynamic instability occurring at the bedside and to prompt assessment for potential hemodynamic interventions.MethodsWe used an ensemble of decision trees to obtain a real-time risk score that predicts the initiation of hemodynamic interventions an hour into the future. We developed the model using the eICU Research Institute (eRI) database, based on adult ICU admissions from 2012 to 2016. A total of 208,375 ICU stays met the inclusion criteria, with 32,896 patients (prevalence = 18%) experiencing at least one instability event where they received one of the interventions during their stay. Predictors included vital signs, laboratory measurements, and ventilation settings.ResultsHSI showed significantly better performance compared to single parameters like systolic blood pressure and shock index (heart rate/systolic blood pressure) and showed good generalization across patient subgroups. HSI AUC was 0.82 and predicted 52% of all hemodynamic interventions with a lead time of 1-h with a specificity of 92%. In addition to predicting future hemodynamic interventions, our model provides confidence intervals and a ranked list of clinical features that contribute to each prediction. Importantly, HSI can use a sparse set of physiologic variables and abstains from making a prediction when the confidence is below an acceptable threshold.ConclusionsThe HSI algorithm provides a single score that summarizes hemodynamic status in real time using multiple physiologic parameters in patient monitors and electronic medical records (EMR). Importantly, HSI is designed for real-world deployment, demonstrating generalizability, strong performance under different data availability conditions, and providing model explanation in the form of feature importance and prediction confidence.
Highlights
Fluid resuscitation and vasoactive therapy are essential in the management of hypotensive patients to support organ perfusion [1,2,3]
Evaluation We report model performance using the area under the receiver operator curve (AUC); sensitivity (Se) known as recall, which is the model’s capacity at predicting the hemodynamic interventions received by patients; specificity (Sp), which quantifies the false predictions of a hemodynamic intervention when the patient did not receive one; and the positive predictive value (PPV) known as precision, which is the fraction of all predictions that truly resulted in an intervention
(58%), 5,159 events resulted in packed red blood cell (PRBC) transfusions (16%), and 11,918 events resulted in significant fluids (36%)
Summary
Fluid resuscitation and vasoactive therapy are essential in the management of hypotensive patients to support organ perfusion [1,2,3]. Rahman et al Critical Care (2021) 25:388 that delayed initiation of vasopressors is associated with higher mortality, fewer vasopressor-free days, and longer time to achieve target mean arterial pressure [5, 6]. Clinical decision support systems that are designed to continuously monitor and identify patients at a high risk of developing hemodynamic instability have the potential to improve the timely recognition of the need for immediate pressure support [7, 8]. Initiation of hemodynamic interventions based on these systems can potentially help avoid complications from organ hypoperfusion and reduce mortality. Single parameter monitoring does not fully describe the entire patient state and can potentially lead to misinterpretation and underestimation of instability. Recognition of hemodynamic instability in critically ill patients enables increased vigilance and early treatment opportunities. We develop the Hemodynamic Stability Index (HSI), which highlights situational aware‐ ness of possible hemodynamic instability occurring at the bedside and to prompt assessment for potential hemody‐ namic interventions
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call