Using machine learning models to predict oxygen saturation following ventilator support adjustment in critically ill children: A single center pilot study

Background In an intensive care units, experts in mechanical ventilation are not continuously at patient’s bedside to adjust ventilation settings and to analyze the impact of these adjustments on gas exchange. The development of clinical decision support systems analyzing patients’ data in real time offers an opportunity to fill this gap. Objective The objective of this study was to determine whether a machine learning predictive model could be trained on a set of clinical data and used to predict transcutaneous hemoglobin oxygen saturation 5 min (5min SpO2) after a ventilator setting change. Data sources Data of mechanically ventilated children admitted between May 2015 and April 2017 were included and extracted from a high-resolution research database. More than 776,727 data rows were obtained from 610 patients, discretized into 3 class labels (< 84%, 85% to 91% and c92% to 100%). Performance metrics of predictive models Due to data imbalance, four different data balancing processes were applied. Then, two machine learning models (artificial neural network and Bootstrap aggregation of complex decision trees) were trained and tested on these four different balanced datasets. The best model predicted SpO2 with area under the curves < 0.75. Conclusion This single center pilot study using machine learning predictive model resulted in an algorithm with poor accuracy. The comparison of machine learning models showed that bagged complex trees was a promising approach. However, there is a need to improve these models before incorporating them into a clinical decision support systems. One potentially solution for improving predictive model, would be to increase the amount of data available to limit over-fitting that is potentially one of the cause for poor classification performances for 2 of the three class labels.

[1]  Leo Breiman,et al.  Bagging Predictors , 1996, Machine Learning.

[2]  Elhassan At,et al.  Classification of Imbalance Data using Tomek Link(T-Link) Combined with Random Under-sampling (RUS) as a Data Reduction Method , 2016 .

[3]  Michael Sauthier,et al.  Creating a High-Frequency Electronic Database in the PICU: The Perpetual Patient* , 2018, Pediatric critical care medicine : a journal of the Society of Critical Care Medicine and the World Federation of Pediatric Intensive and Critical Care Societies.

[4]  G. Bonmarchand Le monitorage et les alarmes ventilatoires , 2000 .

[5]  David A. Landgrebe,et al.  A survey of decision tree classifier methodology , 1991, IEEE Trans. Syst. Man Cybern..

[6]  J. Lacroix,et al.  Risk factors associated with increased length of mechanical ventilation in children , 2012, Pediatric critical care medicine : a journal of the Society of Critical Care Medicine and the World Federation of Pediatric Intensive and Critical Care Societies.

[7]  Mikhail A. Dziadzko,et al.  How Much Oxygen? Oxygen Titration Goals during Mechanical Ventilation. , 2016, American journal of respiratory and critical care medicine.

[8]  W. Karlen,et al.  Pulse oximeter plethysmograph variation and its relationship to the arterial waveform in mechanically ventilated children , 2012, Journal of Clinical Monitoring and Computing.

[9]  K. Gnana Sheela,et al.  Review on Methods to Fix Number of Hidden Neurons in Neural Networks , 2013 .

[10]  Guy Lapalme,et al.  A systematic analysis of performance measures for classification tasks , 2009, Inf. Process. Manag..

[11]  S. Fouzas,et al.  Pulse Oximetry in Pediatric Practice , 2011, Pediatrics.

[12]  Farida Cheriet,et al.  Simulations for Mechanical Ventilation in Children: Review and Future Prospects , 2013, Critical care research and practice.

[13]  J. Salyer,et al.  Neonatal and pediatric pulse oximetry. , 2003, Respiratory care.

[14]  Peter Szolovits,et al.  MIMIC-III, a freely accessible critical care database , 2016, Scientific Data.

[15]  Patrice Hernert,et al.  Development and implementation of explicit computerized protocols for mechanical ventilation in children , 2011, Annals of intensive care.

[16]  M. Singer,et al.  Effect of Conservative vs Conventional Oxygen Therapy on Mortality Among Patients in an Intensive Care Unit: The Oxygen-ICU Randomized Clinical Trial. , 2016, JAMA.

[17]  J. Arnold,et al.  Equilibration Time Required for Respiratory System Compliance and Oxygenation Response Following Changes in Positive End-Expiratory Pressure in Mechanically Ventilated Children , 2018, Critical care medicine.

[18]  M. Wysocki,et al.  A pilot prospective study on closed loop controlled ventilation and oxygenation in ventilated children during the weaning phase , 2012, Critical Care.

[19]  Shamim Nemati,et al.  Machine Learning and Decision Support in Critical Care , 2016, Proceedings of the IEEE.

[20]  C. Cardwell,et al.  Automated versus non-automated weaning for reducing the duration of mechanical ventilation for critically ill adults and children: a cochrane systematic review and meta-analysis , 2015, Critical Care.

[21]  Christopher L. Carroll,et al.  Pediatric acute respiratory distress syndrome: consensus recommendations from the Pediatric Acute Lung Injury Consensus Conference. , 2015, Pediatric critical care medicine : a journal of the Society of Critical Care Medicine and the World Federation of Pediatric Intensive and Critical Care Societies.

[22]  Nitesh V. Chawla,et al.  SMOTE: Synthetic Minority Over-sampling Technique , 2002, J. Artif. Intell. Res..

[23]  H. Brokalaki,et al.  Oxygenation equilibration time after alteration of inspired oxygen in critically ill patients. , 2010, Heart & lung : the journal of critical care.

[24]  A. Nahum,et al.  Time required for partial pressure of arterial oxygen equilibration during mechanical ventilation after a step change in fractional inspired oxygen concentration , 2001, Intensive Care Medicine.

[25]  Nahit Cakar,et al.  Time required for equilibration of arterial oxygen pressure after setting optimal positive end-expiratory pressure in acute respiratory distress syndrome , 2005, Critical care medicine.

[26]  Nitesh V. Chawla,et al.  Editorial: special issue on learning from imbalanced data sets , 2004, SKDD.

[27]  A. Elhassan,et al.  Classification of Imbalance Data using Tomek Link (T-Link) Combined with Random Under-sampling (RUS) as a Data Reduction Method , 2017 .