Author: Matthew Levin; Martin D Chen; Anjan Shah; Ronak Shah; George Zhou; Erica Kane; Garrett Burnett; Shams Ranginwala; Jonathan Madek; Christopher Gidiscin; Chang Park; Daniel Katz; Benjamin Salter; Roopa Kohli-Seth; James B Eisenkraft; Suzan Uysal; Michael McCarry; Andrew B Leibowitz; David L Reich
Title: Differential ventilation using flow control valves as a potential bridge to full ventilatory support during the COVID-19 crisis Document date: 2020_4_21
ID: djul495n_9
Snippet: Two high-fidelity Human Patient Simulator mannequins (HPS Anesthesia Simulator Mannequin Systems, CAE Healthcare, Sarasota, FL) were used for simulation. We tested the system under a variety of simulated patient physiologies likely to be encountered in patients with acute respiratory failure due to COVID-19, using both a GE-Datex-Ohmeda S5 anesthesia machine and a Puritan Bennett 840 ventilator (Medtronic, Minneapolis, MN). The ventilator system .....
Document: Two high-fidelity Human Patient Simulator mannequins (HPS Anesthesia Simulator Mannequin Systems, CAE Healthcare, Sarasota, FL) were used for simulation. We tested the system under a variety of simulated patient physiologies likely to be encountered in patients with acute respiratory failure due to COVID-19, using both a GE-Datex-Ohmeda S5 anesthesia machine and a Puritan Bennett 840 ventilator (Medtronic, Minneapolis, MN). The ventilator system checks were run and the split breathing circuit was connected to the two mannequins, designated Mannequin A and Mannequin B. The ventilator was set to Pressure Control mode and both mannequins were set to simulate identical compliance. With both valves open the driving pressure on the ventilator was adjusted to deliver a tidal volume of 4-6 ml/kg ideal body weight (IBW) to Mannequin A.
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