Temporal Variability in the Sampling of Vital Sign Data Limits the Accuracy of Patient State Estimation
Eytan, Danny, MD, PhD1,2; Jegatheeswaran, Anusha, MD, PhD3,4; Mazwi, Mjaye L., MBChB1,5; Assadi, Azadeh, RN(EC), MN-NP(Pediatrics)1; Goodwin, Andrew J., BEng1,6; Greer, Robert W., BEng, MSc1; Goodfellow, Sebastian D., PhD1; Laussen, Peter C., MBBS1,7
Pediatric Critical Care Medicine: May 31, 2019 - Volume Online First - Issue - p
doi: 10.1097/PCC.0000000000001984
Online Clinical Investigation: PDF Only
BUY
PAP
Abstract
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Objectives: Physiologic signals are typically measured continuously in the critical care unit, but only recorded at intermittent time intervals in the patient health record. Low frequency data collection may not accurately reflect the variability and complexity of these signals or the patient’s clinical state. We aimed to characterize how increasing the temporal window size of observation from seconds to hours modifies the measured variability and complexity of basic vital signs.
Design: Retrospective analysis of signal data acquired between April 1, 2013, and September 30, 2015.
Setting: Critical care unit at The Hospital for Sick Children, Toronto.
Patients: Seven hundred forty-seven patients less than or equal to 18 years old (63,814,869 data values), within seven diagnostic/surgical groups.
Interventions: None.
Measurements and Main Results: Measures of variability (SD and the absolute differences) and signal complexity (multiscale sample entropy and detrended fluctuation analysis [expressed as the scaling component α]) were calculated for systolic blood pressure, heart rate, and oxygen saturation. The variability of all vital signs increases as the window size increases from seconds to hours at the patient and diagnostic/surgical group level. Significant differences in the magnitude of variability for all time scales within and between groups was demonstrated (p < 0.0001). Variability correlated negatively with patient age for heart rate and oxygen saturation, but positively with systolic blood pressure. Changes in variability and complexity of heart rate and systolic blood pressure from time of admission to discharge were found.
Conclusions: In critically ill children, the temporal variability of physiologic signals supports higher frequency data capture, and this variability should be accounted for in models of patient state estimation.
©2019The Society of Critical Care Medicine and the World Federation of Pediatric Intensive and Critical Care Societies
Eytan, Danny, MD, PhD1,2; Jegatheeswaran, Anusha, MD, PhD3,4; Mazwi, Mjaye L., MBChB1,5; Assadi, Azadeh, RN(EC), MN-NP(Pediatrics)1; Goodwin, Andrew J., BEng1,6; Greer, Robert W., BEng, MSc1; Goodfellow, Sebastian D., PhD1; Laussen, Peter C., MBBS1,7
Pediatric Critical Care Medicine: May 31, 2019 - Volume Online First - Issue - p
doi: 10.1097/PCC.0000000000001984
Online Clinical Investigation: PDF Only
BUY
PAP
Abstract
Author Information
Article Metrics
Objectives: Physiologic signals are typically measured continuously in the critical care unit, but only recorded at intermittent time intervals in the patient health record. Low frequency data collection may not accurately reflect the variability and complexity of these signals or the patient’s clinical state. We aimed to characterize how increasing the temporal window size of observation from seconds to hours modifies the measured variability and complexity of basic vital signs.
Design: Retrospective analysis of signal data acquired between April 1, 2013, and September 30, 2015.
Setting: Critical care unit at The Hospital for Sick Children, Toronto.
Patients: Seven hundred forty-seven patients less than or equal to 18 years old (63,814,869 data values), within seven diagnostic/surgical groups.
Interventions: None.
Measurements and Main Results: Measures of variability (SD and the absolute differences) and signal complexity (multiscale sample entropy and detrended fluctuation analysis [expressed as the scaling component α]) were calculated for systolic blood pressure, heart rate, and oxygen saturation. The variability of all vital signs increases as the window size increases from seconds to hours at the patient and diagnostic/surgical group level. Significant differences in the magnitude of variability for all time scales within and between groups was demonstrated (p < 0.0001). Variability correlated negatively with patient age for heart rate and oxygen saturation, but positively with systolic blood pressure. Changes in variability and complexity of heart rate and systolic blood pressure from time of admission to discharge were found.
Conclusions: In critically ill children, the temporal variability of physiologic signals supports higher frequency data capture, and this variability should be accounted for in models of patient state estimation.
©2019The Society of Critical Care Medicine and the World Federation of Pediatric Intensive and Critical Care Societies
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