Mechanical ventilation and resuscitation under water: Exploring one of the last undiscovered environments--A pilot study

James DuCanto; Yannick Lungwitz; Andreas Koch; Wataru Kähler; Laurie Gessell; Jack Simanonok; Norbert Roewer; Peter Kranke; Bernd E Winkler

doi:10.1016/j.resuscitation.2015.05.024

Mechanical ventilation and resuscitation under water: Exploring one of the last undiscovered environments--A pilot study

Resuscitation. 2015 Aug:93:40-5. doi: 10.1016/j.resuscitation.2015.05.024. Epub 2015 Jun 4.

Authors

James DuCanto¹, Yannick Lungwitz², Andreas Koch³, Wataru Kähler³, Laurie Gessell⁴, Jack Simanonok⁴, Norbert Roewer⁵, Peter Kranke⁵, Bernd E Winkler⁶

Affiliations

¹ Department of Anesthesiology, Medical College of Wisconsin, Aurora St. Luke's Medical Center, Milwaukee, USA.
² Department of Anesthesiology, University of Ulm, Germany.
³ German Naval Medical Institute, Kiel-Kronshagen, Germany.
⁴ Department of Hyperbaric Medicine, Aurora St. Luke's Medical Center, Milwaukee, USA.
⁵ Department of Anesthesia and Critical Care, University Hospital of Wuerzburg, Germany.
⁶ Department of Anesthesia and Critical Care, University Hospital of Wuerzburg, Germany. Electronic address: bernd.e.winkler@gmail.com.

PMID: 26051809
DOI: 10.1016/j.resuscitation.2015.05.024

Abstract

Introduction: Airway management, mechanical ventilation and resuscitation can be performed almost everywhere--even in space--but not under water. The present study assessed the technical feasibility of resuscitation under water in a manikin model.

Methods: Tracheal intubation was assessed in a hyperbaric chamber filled with water at 20 m of depth using the Pentax AWS S100 video laryngoscope, the Fastrach™ intubating laryngeal mask and the Clarus optical stylet with guidance by a laryngeal mask airway (LMA) and without guidance. A closed suction system was used to remove water from the airways. A test lung was ventilated to a maximum depth of 50 m with a modified Oxylator(®) EMX resuscitator with its expiratory port connected either to a demand valve or a diving regulator. Automated chest compressions were performed to a maximum depth of 50 m using the air-driven LUCAS™ 1.

Results: The mean cumulative time span for airway management until the activation of the ventilator was 36 s for the Fastrach™, 57 s for the Pentax AWS S100, 53s for the LMA-guided stylet and 43 s for the stylet without LMA guidance. Complete suctioning of the water from the airways was not possible with the suction system used. The Oxylator(®) connected to the demand valve ventilated at 50 m depth with a mean ventilation rate of 6.5 min(-1) vs. 14.7 min(-1) and minute volume of 4.5 l min(-1) vs. 7.6 l min(-1) compared to the surface. The rate of chest compression at 50 m was 228 min(-1) vs. 106 min(-1) compared to surface. The depth of compressions decreased with increasing depth.

Conclusion: Airway management under water appears to be feasible in this manikin model. The suction system requires further modification. Mechanical ventilation at depth is possible but modifications of the Oxylator(®) are required to stabilize ventilation rate and administered minute volumes. The LUCAS™ 1 cannot be recommended at major depth.

Keywords: Cardiopulmonary resuscitation (CPR); Drowning submersion; LUCAS chest compression; Oxylator mechanical ventilation; Pentax AWS S100 airway scope.

MeSH terms

Airway Management
Cardiopulmonary Resuscitation* / instrumentation
Cardiopulmonary Resuscitation* / methods
Environment
Heart Arrest / therapy*
Humans
Intubation, Intratracheal* / instrumentation
Intubation, Intratracheal* / methods
Laryngoscopes*
Manikins
Near Drowning / therapy*
Pilot Projects
Simulation Training / methods
Suction* / instrumentation
Suction* / methods