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Abstract

This article describes a large-scale scenario designed to test the capabilities of a US biocontainment unit to manage a pregnant woman infected with a high-consequence pathogen, and to care for a newborn following labor and spontaneous vaginal delivery. We created and executed a multidisciplinary functional exercise with simulation to test the ability of the Johns Hopkins Hospital biocontainment unit (BCU) to manage a pregnant patient in labor with an unknown respiratory illness and to deliver and stabilize her neonate. The BCU Exercise and Drill Committee established drill objectives and executed the exercise in partnership with the Johns Hopkins Simulation Center in accordance with Homeland Security and Exercise Program guidelines. Exercise objectives were assessed by after-action reporting and objective measurements to detect contamination, using a fluorescent marker to simulate biohazardous fluids that would be encountered in a typical labor scenario. The immediate objectives of the drill were accomplished, with stabilization of the mother and successful delivery and resuscitation of her newborn. There was no evidence of contamination when drill participants were inspected under ultraviolet light at the end of the exercise. Simulation optimizes teamwork, communication, and safety, which are integral to the multidisciplinary care of the maternal-fetal unit infected, or at risk of infection, with a high-consequence pathogen. Lessons learned from this drill regarding patient transportation, safety, and obstetric and neonatal considerations will inform future exercises and protocols and will assist other centers in preparing to care for pregnant patients under containment conditions.

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Simulation of a Spontaneous Vaginal Delivery and Neonatal Resuscitation in a Biocontainment Unit

Abstract

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Supplementary Material