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Abstract
Objective: To compare tidal volume (VT) delivery and ventilation rate between devices for positive pressure ventilation (PPV) during newborn resuscitation.
Methods: Neonatal resuscitation program providers (n = 25) delivered PPV to a newborn manikin in a randomized order with: a self-inflating bag (SIB), a disposable T-piece, a non-disposable T-piece, a stand-alone infant resuscitation system T-piece and the volume-controlled prototype Next StepTM device (KM Medical). All T-pieces used a peak inflation pressure of 20cmH2O and a 5cmH2O positive end-expiratory pressure (PEEP). The SIB neither had a PEEP valve nor manometer. The Next StepTM had a 5cmH2O PEEP valve. The participants aimed to deliver a 5 mL/kg VT (rate 40–60 min−1) for 1 min with each device and each of three compliances (0.5, 1.0 and 2.0 mL/cmH2O). VT and ventilation rate were compared between devices and compliance levels (ANOVA)
Results: All devices, except the Next StepTM delivered a 4–5 mL/kg VT at the low compliance, but three- to four-fold that of the target at the higher compliance levels. The Next StepTM delivered a VT close to target at all compliance levels. The ventilation rate was within 40–60 min−1 with all devices and compliance levels.
Conclusions: Routinely used ventilation devices for newborn resuscitation can triple intended VT and requires further investigation.
Acknowledgements
We would like to thank the neonatal healthcare professionals who contributed to this study.
Declaration of interest
KM Medical provided ‘The Next Step™ Neonatal Resuscitator’ for the study. The company was involved in the design of the study, but not in the data acquisition, data analysis, interpretation of the results, or writing of the manuscript. Dr Haemmerle was in 2008 involved as a University of Auckland Senior Lecturer in the prototype design of the Next Step™ under a research and consultancy agreement between Auckland UniServices Limited and KM Medical (Auckland, NZ). The test lung was designed and manufactured by Auckland University of Technology under the supervision of Dr Haemmerle. Ms van Os and Drs Solevåg, Bach, Cheung and Schmölzer have no potential competing interest relevant to this article to disclose. ALS is supported by the Canadian Institutes of Health Research (operating grant MOP299116, held by PYC and travel award to ALS) and the South-Eastern Norway Regional Health Authority. GMS is supported by a Heart and Stroke Foundation/University of Alberta Professorship for Neonatal Resuscitation and by a Heart and Stroke Foundation of Canada Research Scholarship. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.