• Title of article

    Design and construction of a simplified, gas-driven, pressure-controlled emergency ventilator

  • Author/Authors

    Kr ̈oger, M Technische Universit ̈at Bergakademie Freiberg - Institute for Machine Elements - Design and Manufacturing - Freiberg, Germany , Szlosarek, R Technische Universit ̈at Bergakademie Freiberg - Institute for Machine Elements - Design and Manufacturing - Freiberg, Germany , Teichert, R Technische Universit ̈at Bergakademie Freiberg - Institute for Machine Elements - Design and Manufacturing - Freiberg, Germany , Wetzel, A Technische Universit ̈at Bergakademie Freiberg - Institute for Machine Elements - Design and Manufacturing - Freiberg, Germany , Fichtner, A Kreiskrankenhaus Freiberg gGmbH - Emergency Department - Freiberg, Germany , Reuter, F Technische Universit ̈at Bergakademie Freiberg - Research and Training Mine Reiche Zeche - Freiberg, Germany

  • Pages
    7
  • From page
    175
  • To page
    181
  • Abstract
    Due to the COVID-19 crisis or any other mass casualty situation it might be necessary to give artificial ventilation to many affected patients. Contrarily, the worldwide availability of emergency ventilators is still a shortage, especially in developing countries. Methods Modes of artificial ventilation were compared and the most safe, easy to use, and lung protecting principle was optimized to fit all requirements of both emergency ventilation and cost-effective mass production. Results The presented research results describe a simplified device for a pressure-controlled ventilation which works without electricity according to a known principle. Just pressurized gas and a patient connection is required. The device enables the control of basic ventilator parameters such as peak inspiratory pressure, positive end-expiratory pressure and the ventilation frequency. Further, the device is semiadaptive to the patient's lung stiffness and automatically maintains minute volume through frequency adjustment. The machine can be manufactured by turning, milling and drilling and needs purchased components with costs less than 100 USD. A sterilization and thus a reuse is possible. Discussion The presented development does not describe a ready-to-purchase ventilator, it rather outlines a refined working principle for emergency ventilation and its easiest methods of production with a minimum of requirements. The presented research aims on providing an open-source guideline for production of an emergency ventilator using worldwide available methods and thus should inspire local researchers to do a reverse engineering and eventually to put it into operation following country-specific regulations. For long-term ventilation exceeding emergency purposes, a monitoring of alarms for disconnection and violation of desired ventilator parameters should be established. The ventilator is limited to a fixed ratio between PIP and PEEP. Moreover, the ventilation frequency depends on two parameters, which needs some training. Nevertheless, the ventilator provides basic features to enable an emergency ventilation with minimal prerequisites.
  • Keywords
    Automatic gas-powered ventilator , Pressure control , Emergency ventilation
  • Journal title
    African Journal of Emergency Medicine
  • Serial Year
    2021
  • Record number

    2621774