Multiplex Ventilation: Solutions for Four Main Safety Problems
Autor: | Umur Hatipoğlu, Morgan Elise Sorg, Richard D. Branson, Robert L Chatburn |
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Rok vydání: | 2021 |
Předmět: |
Pulmonary and Respiratory Medicine
medicine.medical_specialty Pressure control ventilation Coronavirus disease 2019 (COVID-19) medicine.medical_treatment Critical Care and Intensive Care Medicine law.invention Positive-Pressure Respiration Patient safety law Internal medicine Tidal Volume Medicine Humans Lung volumes Multiplex Lung Pandemics Tidal volume Mechanical ventilation Ventilators Mechanical business.industry SARS-CoV-2 COVID-19 General Medicine respiratory system respiratory tract diseases Ventilation (architecture) Cardiology business |
Zdroj: | Respiratory care. 66(7) |
ISSN: | 1943-3654 |
Popis: | BACKGROUND: The COVID-19 pandemic has led to an increased demand for mechanical ventilators and concerns of a ventilator shortage. Several groups have advocated for 1 ventilator to ventilate 2 or more patients in the event of such a shortage. However, differences in patient lung mechanics could make sharing a ventilator detrimental to both patients. Our previous study indicated failure to ventilate in 67% of simulations. The safety problems that must be solved include individual control of tidal volume (VT), individual measurement of VT, individualization of PEEP settings, and individual PEEP measurement. The purpose of this study was to evaluate potential solutions developed at our institution. METHODS: Two separate lung simulators were ventilated with a modified multiplex circuit using pressure control ventilation. Parameters of the lung models used for simulations (resistance and compliance) were evidence-based from published studies. Individual circuit-modification devices were first evaluated for accuracy. Devices were an adjustable flow diverter valve, a prototype dual volume display, a PEEP valve, and a disposable PEEP display. Then the full modified multiplex circuit was assessed by ventilating 6 pairs of simulated patients with different lung models and attempting to equalize ventilation. Ventilation was considered equalized when VT and end-expiratory lung volume were within 10% for each simulation. RESULTS: The adjustable flow diverter valve allowed volume adjustment to 1 patient without affecting the other. The average error of the dual volume display was –17%. The PEEP valves individualized PEEP, but the PEEP gauge error ranged from 17% to 41%. Using the multiplex circuit, ventilation was equalized regardless of differences in resistance or compliance, reversing the “failure modes” of our previous study. CONCLUSIONS: The results of this simulation-based study indicate that devices for individual control and display of VT and PEEP are effective in extending the usability and potential patient safety of multiplex ventilation. |
Databáze: | OpenAIRE |
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