Objective: To examine rapidly emerging ventilator technologies during coronavirus disease 2019 and highlight the role of CRISIS, a novel 3D printed solution. Data Sources: Published articles, literature, and government guidelines that describe and review emergency use ventilator technologies. Study Selection: Literature was chosen from peer-reviewed journals and articles were limited to recent publications. Data Extraction: All information regarding ventilator technology was extracted from primary sources. Data Synthesis: Analysis of technology and relevance to coronavirus disease 2019 physiology was collectively synthesized by all authors. Conclusions: The coronavirus disease 2019 pandemic has placed massive stress on global supply chains for ventilators due to the critical damage the virus causes to lung function. There is an urgent need to increase supply, as hospitals become inundated with patients requiring intensive respiratory support. Coalitions across the United States have formed in order to create new devices that can be manufactured quickly, with minimal resources, and provide consistent and safe respiratory support. Due to threats to public health and the vulnerability of the U.S. population, the Food and Drug Administration released Emergency Use Authorizations for new or repurposed devices, shortening the approval timeline from years to weeks. The list of authorized devices varies widely in complexity, from automated bagging techniques to repurposed sleep apnea machines. Three-dimensional printed ventilators, such as “CRISIS,” propose a potential solution to increase the available number of vents for the United States and abroad, one that is dynamic and able to absorb the massive influx of hospitalized patients for the foreseeable future.
The coronavirus disease of 2019 (COVID-19) has altered medical practice around the globe and revealed critical deficiencies in hospital supply chains ranging from adequate personal protective equipment to life-sustaining ventilators for critically ill hospitalized patients. We developed the CRISIS ventilator, a gas-powered resuscitator that functions without electricity, and which can be manufactured using hobby-level three-dimensional (3D) printers and standard off-the-shelf equipment available at the local hardware store. CRISIS ventilators were printed and used to ventilate sedated female Yorkshire pigs over 24-h. Pulmonary and hemodynamic values were recorded throughout the 24-h run, and serial arterial blood samples were obtained to assess ventilation and oxygenation. Lung tissue was obtained from each pig to evaluate for signs of inflammatory stress. All five female Yorkshire pigs survived the 24-h study period without suffering from hypoxemia, hypercarbia, or severe hypotension requiring intervention. One animal required rescue at the beginning of the experiment with a traditional ventilator due to leakage around a defective tracheostomy balloon. The wet/dry ratio was 6.74 ± 0.19 compared to historical controls of 7.1 ± 4.2 (not significantly different). This proof-of-concept study demonstrates that our 3D-printed CRISIS ventilator can ventilate and oxygenate a porcine model over the course of 24-h with stable pulmonary and hemodynamic function with similar levels of ventilation-related inflammation when compared with a previous control porcine model. Our work suggests that virtual stockpiling with just-in-time 3D-printed equipment, like the CRISIS ventilator, can temporize shortages of critical infrastructure needed to sustain life for hospitalized patients.
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