Introduction
The COVID-19 pandemic in 2021 has accelerated the demand for oxygen supplies globally. Many countries have not seen such high demand before the pandemic to meet their daily oxygen requirement (Usher 2021). Worldwide, governments are scaling up their existing facilities to fill the oxygen demand. In the healthcare system, oxygen is an essential medicine required at all levels. It is estimated that 20–40% of deaths due to pneumonia could be prevented using oxygen therapy (WHO 2021). Medical air in hospital settings is widely used for mechanical ventilation, infant resuscitation, aerosol drug delivery, and neonatal environment control (Edwards et al. 2018).
Oxygen cylinders, oxygen concentrators, liquid oxygen, and membrane separator oxygen enrichers are commonly used for oxygen therapy (Rees and Dudley 1998). In the current COVID-19 pandemic, long-term oxygen therapy is required at both hospitals and in-home settings that the respiratory physician should supervise for optimal treatment (Rees and Dudley 1998). Unprecedented production of oxygen and refilling of cylinders can give rise to the risk of impurities, which could lead to an increase in hidden mortality. However, it would be difficult to assess the increase in mortality due to the impurity of the oxygen gas. Hence, the purity of the oxygen needs to be regulated by the respective authorities (Edwards et al. 2018). Higher oxygen production can give rise to a possibility of contamination.
In a recent study, the CO2 impurity was reported in oxygen cylinders above the recommended threshold level (Edwards et al. 2018). In previous studies, various health effects were reported due to the common air pollutants (WHO 2005). It was also observed that unintentional inhalation of NO in industrial regions might change the PaO2 (Benzing et al. 1999). Edwards et al. (2018) also mentioned onsite production of medical air poses a risk of raising the CO2 and NOx (nitric oxides) concentration above the United States Pharmacopeia (USP) threshold (Edwards et al. 2018). This rise of these trace gases may be due to the dryer that is used to capture the CO2 contaminant and humidity.
Impurity sources can be arising due to the production and delivery systems, as well as from the environmental pollution levels near the regions. According to the FDA guidelines, medical gases should be checked for any adulteration during production, packaging, delivery, and manufacturing facilities (FDA 2015). Here, we would like to highlight few points for policymakers/local authorities (Table 1) and for the general public (Table 2) to create awareness and recommendations to improve the quality of oxygen.
Another reason for the increase in the COVID-19 mortality can also be due to the black fungus, which are present in the environment (Richardson 2009). This could lead to mucormycosis, which could be a fatal disease for people who have weakened immune systems (Spellberg et al. 2005). In the nasal tract, black fungus develop due to the poor quality of water used to hydrate the oxygen in a hospital setting (piped and cylinders). This fungus grows in the nostril, travels towards the eyes (Klotz et al. 2000), and then towards the brain, which can paralyze the nerves (Escobar and Del Brutto 1990), cause permanent damage to the eye, or even could lead to a heart attack (Naik et al. 2021; Jackman and Simonsen 1992).
An evidence-based advisory for screening, diagnosis, and management of mucormycosis developed by Cornely et al. (2019) should be followed and need to be updated considering the recent evidence of mucormycosis in the COVID-19 pandemic (Cornely et al. 2019). In a hospital setting, constantly monitor distilled water for oxygen hydration before using it in oxygen therapy devices (Cahill and Heath 1990). Use of tap water even after boiling is not recommended in the humidifier as after some time; impurities (micro-metals and minerals/salts) start to buildup, leading to severe health issues even after using life-saving precious oxygen therapy.
Globally, we are facing an emergency that needs support from authorities and the community to minimize the suffering and improve the well-being of all. In lower- and middle-income countries, oxygen purity can be a significant issue that requires local interventions at the earliest. Countries where there is prevalence of malaria, sepsis, pneumonia, and other ailments should also prioritize where oxygen therapy requires at large (Usher 2021).
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Vivek Singh Malik, Khaiwal Ravindra, and Meenu Singh all contributed equally in writing, reviewing, and final editing of the manuscript.
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Malik, .S., Ravindra, K. & Singh, M. COVID-19 and increasing demand for medical oxygen: can impurity be a problem?. Environ Sci Pollut Res 28, 66519–66521 (2021). https://doi.org/10.1007/s11356-021-16385-x
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DOI: https://doi.org/10.1007/s11356-021-16385-x