Michael E Valente1, Judy A Sherif1, Colleen G Azen2, Phung K Pham1, Calvin G Lowe3. 1. Division of Emergency and Transport Medicine, Children's Hospital Los Angeles, CA, USA. 2. Southern California Clinical and Translational Science Institute, Children's Hospital Los Angeles and University of Southern California, Los Angeles, CA, USA. 3. Division of Emergency and Transport Medicine, Children's Hospital Los Angeles, CA, USA; Department of Pediatrics, Keck School of Medicine, University of Southern California, Los Angeles, CA, USA. Electronic address: clowe@chla.usc.edu.
Abstract
OBJECTIVE: The purpose of this study is to measure peak acceleration forces during interfacility transport; examine whether drops in cerebral oxygenation occurred; and test the associations between cerebral oxygenation, acceleration, and patient positioning. METHODS: A cerebral oximeter (INVOS-5100C; Somanetics, Minneapolis, MN) monitored regional saturation of oxygen (rSO2 [cerebral oxygenation]) in pediatric and neonatal patients (N = 24) transported between facilities by ground ambulance, helicopter, or fixed wing aircraft. An accelerometer (GP1; SENSR, Georgetown, TX) bolted to the isolette or gurney recorded z-axis (aligned with the spine) accelerations. RESULTS: The z-axis peak accelerations (absolute values of g) by transport type were as follows: ground ambulance takeoff mean = 0.16 and landing mean = 0.08, helicopter takeoff mean = 0.16 and landing mean = 0.05, fixed wing aircraft takeoff mean = 0.14 and landing mean = 0.20. During takeoff, 2 of 7 patients in the head-to-front of vehicle position experienced rSO2 drop. During landing, 4 of 13 patients in the head-to-back of vehicle position experienced rSO2 drop. There were no significant associations of rSO2 drop during takeoff and landing with patient positioning or with z-axis peak acceleration. CONCLUSION: Acceleration forces of pediatric and neonatal interfacility transport are small and comparable in magnitude. The relationship between rSO2 drop and patient positioning was not significant in this pilot study.
OBJECTIVE: The purpose of this study is to measure peak acceleration forces during interfacility transport; examine whether drops in cerebral oxygenation occurred; and test the associations between cerebral oxygenation, acceleration, and patient positioning. METHODS: A cerebral oximeter (INVOS-5100C; Somanetics, Minneapolis, MN) monitored regional saturation of oxygen (rSO2 [cerebral oxygenation]) in pediatric and neonatal patients (N = 24) transported between facilities by ground ambulance, helicopter, or fixed wing aircraft. An accelerometer (GP1; SENSR, Georgetown, TX) bolted to the isolette or gurney recorded z-axis (aligned with the spine) accelerations. RESULTS: The z-axis peak accelerations (absolute values of g) by transport type were as follows: ground ambulance takeoff mean = 0.16 and landing mean = 0.08, helicopter takeoff mean = 0.16 and landing mean = 0.05, fixed wing aircraft takeoff mean = 0.14 and landing mean = 0.20. During takeoff, 2 of 7 patients in the head-to-front of vehicle position experienced rSO2 drop. During landing, 4 of 13 patients in the head-to-back of vehicle position experienced rSO2 drop. There were no significant associations of rSO2 drop during takeoff and landing with patient positioning or with z-axis peak acceleration. CONCLUSION: Acceleration forces of pediatric and neonatal interfacility transport are small and comparable in magnitude. The relationship between rSO2 drop and patient positioning was not significant in this pilot study.