key: cord-336259-gtb8ictv authors: Polkinghorne, A.; Branley, J. title: Evidence for decontamination of single-use filtering facepiece respirators date: 2020-05-27 journal: J Hosp Infect DOI: 10.1016/j.jhin.2020.05.032 sha: doc_id: 336259 cord_uid: gtb8ictv Single-use filtering face respirators (FFRs) are critical pieces of personal protective equipment for healthcare workers treating patients with suspected upper respiratory tract pathogens. Experiences during pandemics in the 2000s, as well as the ongoing COVID-19 pandemic caused by the SARS-2-CoV2, have highlighted concerns over the pressures that sustained respiratory virus pandemics may have on supplies of FFRs globally. Decontamination of FFRs has been posited as one solution to support the re-use of FFRs with a growing body of literature over the last 10+ years beginning to examine both the efficacy of disinfection of contaminated FFRs but also the impact of the decontamination process on the FFR’s performance. Physical and chemical methods of decontamination have been tested for treatment of FFRs with ultraviolet germicidal irradiation, sterilization by steam, ethylene oxide and vaporous hydrogen peroxide, demonstrating the most promising results thus far. Many of these methods utilize existing equipment that may already be available in hospitals and could be re-purposed for FFR decontamination. Importantly, some methods may also be replicated on household equipment, broadening the utility of FFR decontamination across a range of healthcare settings. Utilizing techniques to experimentally contaminate FFRs with a range of microorganisms, most decontamination methods appear to reduce the risk of the mask as a source of infection to the wearer and others to negligible levels. The performance of the filter, especially the efficiency of particle penetration following treatment, varied greatly depending on the processing method as well as the model of the filter itself, however. Urgent regulatory body-supported research is required to endorse the routine decontamination of FFRs. In emergency settings, these methods should nevertheless be carefully considered as one strategy to address potential shortfalls in supplies of FFRs for healthcare workers. Filtering face piece respirators (FFR) are standard and critical personal protection devices designed to protect health-care workers (HCWs) required to undertake airborne precautions in treating patients with suspected respiratory pathogens 1 . Protection is facilitated by a close fit and filtration of >95% of very small (0.3 micron) test particles from the inhaled air of the wearer 1, 2 . As per the National Institute for Occupational Safety and Health (NIOSH) guidelines, the service life of a N95 FFR is not specified, however, its use should be limited by assessments of damage, soiling or an increase in breathing resistance 2 . As such, N95 respirators are typically considered to be 'single-use', involving a single donning and doffing by a HCW prior to being discarded appropriately. Previous outbreaks of respiratory viruses such as the 2004 SARS outbreak 3 influenza pandemic 4 , have highlighted the risks of shortages of FFRs at the hospital level, leading to potential for significant rates of infection amongst HCWs 3 . In preparation for future pandemics that might likely lead to similar shortages, countries continue to stockpile medical devices such as N95 respirators with at least one study suggesting that public health agencies would need to significantly increase the stocks of respirators and other masks available to meet scenarios where 20 -30% of a population becomes affected 5 . As an alternative to stockpiling of respirators, HCWs may also choose to 'extend the use' of FFRs and/or 'reuse' masks, involving donning and doffing of masks multiple times. Some recommendations exist for extended or limited reuse of FFRs during pandemics for certain types of respiratory viruses but not others 1 . One of the principle concerns with abandoning disposal of respiratory masks is the potential for the masks to become contaminated with fluids, etc. that may affect respirator performance as well as the potential for the masks to act as reservoirs of infectious microorganisms. The latter is of concern with quantitative PCR (qPCR) screening of N95 FFRs worn by HCWs exposed to patients during an influenza season found to be contaminated with influenza virus. While the risk of reaerosolisation of viable viral particles from contaminated FFRs has been assessed as low 6 , virus-contaminated N95 FFRs may also act as a source of hand contamination 7 . Decontamination of masks to facilitate safe re-use has been postulated as one, albeit controversial 8 , solution with a number of studies over the last 20 years investigating the effectiveness of different decontamination methods on the performance of the treated FFR in protecting the HCW and/or removing the potential of the FFR to act as a fomite [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] . It has been suggested that for N95 FFR decontamination to be considered successful, the method must remove the presence of the infectious agent, not harm the user and not compromise the function of the respirator itself 20 . The global spread of the SARS-CoV-2 virus, the cause of a pneumonia-like illness referred to as COVID-19 21 , has placed critical demands on the supply of respirators and other medical supplies. As in previous pandemics 22 , the use of N95 respirators alongside other airborne precautions appears to be the cornerstone of effective infection control schemes to protect HCWs treating seriously ill individuals. For example, 4.7% (10/231) of staff who did not wear N95 respirators, nor performed frequent disinfection by handwashing, became infected with SARS-CoV-2 virus compared to their colleagues who wore N95 respirators and followed frequent disinfection protocols (0.0%; 0/278) over the same time period, despite the fact that the latter group worked in much higher risk areas. Highlighting the significant potential for mask decontamination to meet the critical need for N95 FFRs during the current COVID-19 outbreak, NIOSH is encouraging studies to assess the performance of decontaminated N95 FFRs 23 . In this rapid review, we summarise previous and current research into the methods for decontamination and subsequent assessment of N95 respirators for contamination and/or filter performance. Considerations in recommending the limited reuse of FFR for HCWs have also been thoroughly discussed previously 1 . Together, this information should serve as a resource to advance research into the role of FFR reuse in emergency situations. Relevant English language published literature on FRR decontamination was identified by searching of the Medline bibliographic database (https://pubmed.ncbi.nlm.nih.gov/). Studies into FFR decontamination have focussed on two parameters, including (i) changes to the performance of the filter and/or (ii) the reduction in microbial burden following the decontamination procedure. Respirator performance is primarily focussed on filtration efficiency with NISOH certification requiring a filtration efficiency of ≥ 95% or ≤ 5% penetration against challenges from a dispersed NaCl aerosol in laboratory conditions 24 . A number of decontamination studies have investigated the impact of decontamination on filtration efficiency 9, 10, 13, 15 . In addition to penetration efficiency, additional criteria that have been investigated less frequently include filter air flow resistance, fit testing, and the stability of the physical components (e.g. straps, nose bridge) of the mask, over concerns that that decontamination may lead to physical damage of the FFR. In terms of the efficacy of FFR decontamination to control the microbial burden, the most relevant method has involved experimental inoculation of the masks with influenza virus prior to decontamination 14, 15 , followed by viral recovery using culture and/or qPCR quantification of viral loads on extracted FFR material. As an alternative to influenza virus, experimental inoculation with MS2 viral coliphage has also been used in studies of FFR contamination and decontamination 6, 17, 19, [25] [26] [27] . Bacteria, including Staphylococcus aureus 13 and the spores of Bacillus subtilis 11 have also been loaded onto FFRs to assess decontamination efficacy. The following section outlines the published literature investigating different methods for decontamination of FFRs. The key findings of these studies, divided by the method utilised for decontamination, are summarised in Table 1 . While the majority of studies have investigated the use of existing methods and equipment that are typically used and available for disinfection within a health setting, a number of novel decontamination methods have also been investigated and will be described including those studies that have investigated the use of common household equipment such as ovens 9, 11, 14, 15 , microwaves 9, 14, 15, 17, 28 and rice cookers 11 . The results of steam mediated FFR decontamination studies suggest that this method is extremely promising, perhaps more than any of the methods reported in this review. Sterilisation by steam is widely used in health care settings as it is a non-toxic, cost-effective and rapid method for microbial destruction 29 . Microbial destruction is achieved by direct contact with steam, which leads to the irreversible coagulation and denaturation of microbial proteins 29 . A variety of methods have been investigated to achieve steam sterilisation of FFRs, including common health setting equipment (e.g. autoclaves) as well as makeshift methods using microwaves, ovens etc. For the latter approaches, steam generation is typically achieved by the introduction of vessels containing water, with the exposed faces of the FFR positioned above the vessel to allow steam to be distributed across the FFR surface 15 . Microwave steam bags, designed for the disinfection of equipment for feeding infants, have also been investigated for the decontamination of individual FFRs 17 . Decontamination of FFRs experimentally contaminated with either influenza virus or its substitute, bacteriophage MS2, reveal consistently successful and significant reductions in viral loads 14, 15, 17 . Steam sterilisation of FFRs has also shown to be 100% effective in killing B. subtilis spores on FFRs 11 . Filter performance does not appear to be significantly impacted either with autoclave, oven and microwave-based methods demonstrated to have no significant effect on FFR particle filtration 10, 15, 17 , including after several cycles of exposure to steam decontamination 12 . FFR fit does not appear to be affected as well 28 . Moist heat with a relative humidity of between 60 -80% has also be assessed for FFR decontamination 14, 15 . Oven-generated moist heat was found to reduce influenza viral loads on most models of FFRs to below detectable limits 14, 15 without a significant impact on the mean penetraton of 1% NaCl aerosols at a 300-nm particle size 15 . Dry heat is a useful method for sterilisation of materials that might be damaged by moist heat, however, it is more time consuming since heat penetration and microbial destructions rates are slower 29 . Several studies have investigated the impact of dry heat on microbial burden and/or the performance of the FFR post-treatment with researchers finding differing results depending on the device used to generate dry heat. A study by Lin et al. 11 found that dry heating of experimentally contaminated FFRs in a traditional electric rice cooker for only three minutes (149 -164°C; no water added) achieved >99% B. subtilis spore destruction. This method does also not appear to impact on the penetration of particles or the pressure drop through the treated mask 10 . The use of other methods for dry heat decontamination of FFRs are less promising. Microwave oven derived heat decontamination for only two minutes was found to melt FFR components to the point that they were considerable unwearable 9 . The metal nosebands of FFRs may also cause arcing, during exposure to microwaves. Poor results were also found with dry oven baking for 1 hr at temperatures ranging from 80 -120°C, with various models tested found to have filter aerosol penetrations >5% following treatment 9 . Ultraviolet germicidal irradiation (UVGI) has been one of the most heavily investigated of the methods for FFR decontamination. UVGI utilises ultraviolet light to kill viruses from the energy contained within the electromagnetic short-waves (254 nm) 15 . UV irradiation has been shown to be an effective method for inactivation of SARS-CoV virus 30 . Experimental studies have found that UVGI, deployed at different doses, is effective (i.e. ≥3 log reduction) in neutralising influenza or MS2 virus inoculated onto the surfaces of FFRs 14, 15, 19 . Vo et al. 19 found that decontamination efficacy was time-dependent, with a ≥3 log reduction observed only after 3 hr UVGI exposure. Effective decontamination time could be shortened to 15 min by significantly increasing the UVGI dosage, however 15 . When the filter performance of UVGI-treated FFRs was tested, differences in the mean penetration test results using a 1% NaCl aerosol were found to be not significant 9, 15, 18 . Changes to flow resistance were similarly unaffected. At higher doses (e.g. 950 J/cm 2 ), however, UVGI was noted to significantly deteriorate the layers of respirator material while also weakening the breaking strength of the FFR straps 18 . It was noted that visible deterioration alternatively could be used as an indicator on the number of UVGI cycles an individual FFR could be limited to 18 . In terms of the practical application of UVGI, many health care organisations already have UVGI systems that could be repurposed for FFR decontamination if required, with staff training potentially required to limit UVGI expose to eyes and skin. Gaseous phase chemicals are routinely used in health-care settings to sterilise medical products that are not suitable for treatment by steam sterilisation 29 , with a number also tested for their use in decontamination of FFRs (Table 1) . Vaporised hydrogen peroxide (VHP) is a vapour form of hydrogen peroxide (H 2 O 2 ), used as a low-temperature sterilant in health-care settings 31 . VHP decontamination does not appear to affect FFR particle penetration and filter airflow resistance after single 9 or multiple cycles of treatment 12 . A single VHP vapor cycle was found to reduce (> 4 log) the infectious dose of spiked bacteriophage to levels below the infectious dose required for most respiratory viruses 32 . Ethylene oxide (EtO) is a colourless gas that causes alkylation of proteins, impeding normal metabolism and replication in cells 29 . EtO sterilisation is a relatively slow procedure, requiring treatment and then extensive aeration post-treatment. Assessment of filter performance following EtO decontamination suggests that filter aerosol penetration, as well as appearance and filter airflow resistance are unaffected in treated filters 9 . Furthermore, changes in filter penetration following three cycles of treatment were <5% 12 . Several studies have investigated the efficacy of FFR decontamination using physical cleaning or submersion.in liquid chemicals. Bleach has been shown to have strong bactericidal and virucidal activity when used to decontaminate experimentally inoculated FFRs 11, 19 , however, the effect on filter performance appears to be variable with a decrease in FFR particle filtration noted for certain FFR models tested 9, 10, 12 . As an alternative, physical removal with bleach wipes has also been tested on FFRs contaminated with mucin and viable S. aureus, revealing significant microbial attenuation and little or no impact on particle penetration performance 13 . Cleaning with other wipes were also investigated in this study, with inert wipes (no antimicrobial activity) showing moderate cleaning efficacy while benzalkonium-embedded wipes produced similar results to the bleach cleaning wipes. Physical degradation and changes to FFR particle penetration were negligible 13 , although results varied depending on the models tested. Immersion in liquid hydrogen peroxide was also found to not impact on filter performance 12 . Although disinfection was not tested, it could be predicted that it would be effective given that this chemical has strong germicidal activity 29 . Immersion in alcohol (ethanol & isopropanol) were found to have small impact on FFR particle filtration in a recent study 10 . An obvious concern associated with the use of chemical methods is related to the potential for harmful chemical residues to remain on the FFR after decontamination, providing the potential for respiratory and/or skin irritation for the wearer. This fear was confirmed by a study from Salter et al. 33 revealing that residual chemicals could be detected on FFRs following treatment with a variety of gaseous and liquid decontaminants. For the majority of chemicals measured, it was concluded that the amount of chemical detected would be below the permissible exposure limit of the wearer. A noticeable odour was also detected that some wearers may be unable to tolerate, an observation that was also made in a previous study examining bleach decontamination of FFRs 9 . In terms of safety, one noticeable exception was the use of EtO, a toxic carcinogen 29 , with harmful carcinogenic and mutagenic residues detected on the FFRs post-treatment 33 . The ongoing COVID-19 pandemic has placed significant pressures on the availability of critical HCW PPE such as FFRs for front-line staff required to implement airborne precautions. The ability to stockpile sufficient FFRs to endure a 6-week influenza pandemic in the USA was previously identified as a cause of significant concern health care officials 20 and this concern has now come to reality during the COVID-19 pandemic 20 . While adopting extended wear is one potential solution to address this FFR shortage 1 , this review has highlighted the growing body of literature providing evidence that FFRs can be biologically decontaminated for reuse. The impact that decontamination has on filter particle penetration is less compelling, with much still unknown about how these processes will affect other aspects of FFR performance such as fit and seal. Of the methods that have been investigated to date, decontamination by steam, UVGI and HPV hold the most potential as solutions that can be employed using existing health care facility infrastructure. In the case of steam, this method has the potential to be used by HCWs outside of the healthcare setting, where required, by co-opting household equipment (e.g. microwaves, ovens, rice cookers) to assist with steam generation. These methods appear to be very effective at biological decontamination of FFRs contaminated with bacteria and viruses, addressing one of the primary concerns over the re-use of FFRs, namely that contaminated masks may become a fomite for infection of the HCW or susceptible patients. In terms of FFR performance, FFR particle penetration, perhaps the most important aspect to the function of an FFR, also appears to be unaffected after treatment with these methods, suggesting that decontaminated FFRs will provide some level of protection from aerosolised infectious particles, certainly more so than not wearing an FFR at all. Evidence for the use of rice cookers and other household implements for FFR decontamination also highlights the potential for other non-conventional methods that may be available to support the reuse of FFRs. One unexplored option involves the use of solar disinfection, an unconventional method that relies on the use of energy from the sun to obtain sufficiently high temperatures to inactive or destroy microorganisms 34 . This method has been successfully used to decontaminate water containing RNA viruses at high temperatures 35 and may represent a free solution available for HCWs to perform decontamination of their own personal protective equipment. The decision over which method to employ for decontamination of FFRs will almost certainly need to take into consideration the throughput capacity of the chosen method, the time required for decontamination, including the period of time required after treatment for the FFR to be worn safely, particularly for chemical methods for decontamination such as EtO and VHP. The number of cycles with which an individual FFR can be recycled also needs to be carefully considered. While multiple cycles (e.g. three) of FFR decontamination did not appear to impact FFR function more than a single cycle for most methods investigated, factors such as the way the masks are stacked and the relative level of exposure to processing conditions have been suggested to influence the 'survival' of FFRs after decontamination 12 . In the case of UVGI, the dosage also needs to be carefully planned with higher levels of UVGI dosage having a measurable deleterious effect on the respirator material than lower doses 18 . In worst case scenarios, it has been suggested that the physical degradation of the respirator material could be used as a visual cue to determine when a treated FFR should be discarded 18 . There are three other important issues that need to be considered, however, when considering the relative risk and benefit of FFR decontamination: • FFR integrity and performance following decontamination appears to be modelspecific. Hundreds of models of FFR are currently approved for use by HCWs around the world. As highlighted by Mills et al. 16 , FFR models vary greatly in their design including the FFR shape, material composition, and other features such as pleats and flaps with many of these design features potentially effecting the efficacy of biological contamination as well as the physical degradation of the FFR. For example, in the latter study, UVGI decontamination efficiency was noted to be potentially affected by shadowing created by the presence of ridges in the mask 16 . Physical damage to the mask as filter performance also appears to vary between models when treated by the same method 12 . These model-specific differences pose significant challenges to regulators considering general recommendations over the use of mask decontamination and re-use, with none of the studies described providing sufficient replicated data to support the use of any one method for all models available. In the absence of this information, when implementing any of the decontamination methods described in this review, care needs to be taken to ensure that (a) the methods are repeated exactly as described in the published studies; and (b) the FFR models being treated are similar to, it not identical, to those tested in the study. • The impact of decontamination processes on other FFR performance factors other than particle penetration have yet to be fully explored. While particle penetration should be the most important factor to measure FFR penetration, more information is required about other factors such as filter air flow resistance, fit testing, the stability of physical components such as straps, as well as the impact of contamination on filter comfort and donning ease need to be studied in detail 28 . A number of studies have included these FFR performance factors in their analyses 9, 12, 28 , however, most only examine filter penetration. • Willingness of HCWs and administrators to adopt FFR decontamination and reuse. The most obvious concern arising from any discussion of filter decontamination is that the methods investigated all involve 'off-use' of government-regulated single use equipment. Manufacturers of FFRs recommend that masks should be disposed of after a single use and that interference (e.g. cleaning) will disqualify the devices from use as filtering devices. Approval by regulators for mask decontamination might also been seen as acknowledgement that administrators have failed to provide appropriate amounts of PPE to HCWs. Conversely, a recent survey by Nemeth et al. showed that HCWs hold significant concerns about the availability of FFRs during a highmortality pandemic event 36 and that use of decontamination methods to support reuse of FFRs was seen favourably, as long as government agencies would provide approval to support their use. Extensive training in FFR decontamination by HCWs would need to be implemented after the development of standard operating procedures for this infection control procedure 37 . An obvious limitation of this rapid review is that information was biased towards Englishlanguage research articles published in scientific journals listed in the Medline bibliographic database. Other information on FFR decontamination may be available (e.g. 'grey' literature) and could be reviewed as part of a more systematic and comprehensive review on this topic at a later date. Resource shortages through excessive demand and supply chain limitations have led to the need to consider reusing items normally regarded as single use. The lessons learned from this crisis may lead to a greater appreciation of the need for conservation of life-saving protective equipment. Necessity is indeed the mother of invention, and we may learn that using less is beneficial in the developed as well as the developing world. Rice cooker -100% bactericidal to Bacillus subtilis spores 11 No significant differences in FFR particle filtration - 10 Microwave <5% decrease in FFR particle penetration after three decontamination cycles -12 ->4 Log10 TCID 50 reduction in spiked influenza viral load 14 No significant decrease in FFR particle filtration >4 Log10 TCID 50 reduction in spiked influenza viral load 15 No significant decrease in FFR particle filtration >99.9% MS2 virus challenge decontamination efficiency 17 Oven / Incubator <5% decrease in FFR particle penetration after three decontamination cycles -12 ->4 Log10 TCID 50 reduction in spiked influenza viral load 14 No significant decrease in FFR particle filtration >4 Log10 TCID 50 reduction in spiked influenza viral load 15 Rice cooker -100% bactericidal to B. subtilis spores 11 Autoclave -100% bactericidal to B. subtilis spores 11 No significant decrease in FFR particle filtration - 10 Physical -Irradiation UV-C <5% decrease in FFR particle penetration after three decontamination cycles - 12 No significant decrease in FFR particle filtration >4 Log10 TCID 50 reduction in spiked influenza viral load 15 Small decrease (<1.25%) in FFR particle filtration - No significant decrease in FFR particle filtration; measurable chlorine off-gassing - 9 Ethanol (70 -80%) -80% bactericidal to B. subtilis spores 11 Decrease in FFR particle filtration - 10 Isopropanol (100%) Decrease in FFR particle filtration - 10 Liquid hydrogen peroxide <5% decrease in FFR particle penetration after three decontamination cycles - 12 Benzalkonium chloride wipes <5% decrease in FFR particle penetration 68 ->99.9% reduction in inoculated Staphylococcus aureus 13 Inert wipes <5% decrease in FFR particle penetration 59-90% reduction in inoculated S. aureus 13 Bleach wipes <5% decrease in FFR particle penetration >99.9% reduction in inoculated S. aureus 13 Ethylene oxide No significant decrease in FFR particle filtration -9 <5% decrease in FFR particle penetration after three decontamination cycles - 12 Vaporised hydrogen peroxide / hydrogen peroxide gas plasma No significant decrease in FFR particle filtration -9 <5% decrease in FFR particle penetration after three decontamination cycles - 12 ->4 Log10 reduction in spiked bacteriophage viral load 32 >5% decrease in FFR particle penetration after three decontamination cycles - Considerations for recommending extended use and limited reuse of filtering facepiece respirators in health care settings Guide to the Selection and Use of Particulate Respirators. Centre for Disease Control and Prevention Hung LS The SARS epidemic in Hong Kong: what lessons have we learned? Evaluation of respiratory protection programs and practices in California hospitals during the 2009-2010 H1N1 influenza pandemic Potential demand for respirators and surgical masks during a hypothetical influenza pandemic in the United States Shaffer RE Reaerosolization of MS2 bacteriophage from an N95 filtering facepiece respirator by simulated coughing Transfer of bacteriophage MS2 and fluorescein from N95 filtering facepiece respirators to hands: Measuring fomite potential Wiwanitkit V Face mask decontamination and reuse: is it ok? Shaffer RE Evaluation of five decontamination methods for filtering facepiece respirators Lin WY Filter quality of electret masks in filtering 14.6-594 nm aerosol particles: Effects of five decontamination methods Relative survival of Bacillus subtilis spores loaded on filtering facepiece respirators after five decontamination methods Shaffer RE Evaluation of multipe (3-cycle) decontamination processing for filtering Facepiece Respirators Wander JD Cleaning of filtering facepiece respirators contaminated with mucin and Staphylococcus aureus A pandemic influenza preparedness study: use of energetic methods to decontaminate filtering facepiece respirators contaminated with H1N1 aerosols and droplets Hinrichs SH Effectiveness of three decontamination treatments against influenza virus applied to filtering facepiece respirators Ultraviolet germicidal irradiation of influenza-contaminated N95 filtering facepiece respirators Shaffer RE Evaluation of microwave steam bags for the decontamination of filtering facepiece respirators Effects of Ultraviolet Germicidal Irradiation (UVGI) on N95 Respirator Filtration Performance and Structural Integrity Development of a test system to evaluate procedures for decontamination of respirators containing viral droplets Reuseability of facemasks during an influenza pandemic Epidemiology, Pathogenesis, and Control of COVID-19 Transmission of 2009 pandemic influenza A (H1N1) virus among healthcare personnel-Southern California Respirator Assessments to Support the COVID-19 Response. 2020. 24. NIOSH. Determination of particulate filter efficiency level for N95 series filters against solid particulates for non-powered, air-purifying respirators standard testing procedure (STP) Shaffer RE Evaluation of the survivability of MS2 viral aerosols deposited on filtering face piece respirator samples incorporating antimicrobial technologies Pandemic Influenza A (H1N1) Virus (pH1N1) in Surface Survival Studies on N95 Filtering Facepiece Respirators Wander J Method for contamination of filtering facepiece respirators by deposition of MS2 viral aerosols Impact of three biological decontamination methods on filtering facepiece respirator fit, odor, comfort, and donning ease Infection control: the role of disinfection and sterilization Taylor DR Inactivation of the coronavirus that induces severe acute respiratory syndrome, SARS-CoV Terminal sterilization of medical devices using vaporized hydrogen peroxide: a review of current methods and emerging opportunities Hydrogen peroxide vapor sterilization of N95 respirators for reuse Wander JD Analysis of residual chemicals on filtering facepiece respirators after decontamination The problem of drinking water access: A review of disinfection technologies with an emphasis on solar treatment methods Solar Disinfection of Viruses in Polyethylene Terephthalate Bottles Preparing for an Influenza Pandemic: Hospital Acceptance Study of Filtering Facepiece Respirator Decontamination Using Ultraviolet Germicidal Irradiation Disinfection of reusable elastomeric respirators by health care workers: A feasibility study and development of standard operating procedure We thank Ethan Polkinghorne for assistance in identifying and reviewing relevant literature and Prof Lyn Gilbert for helpful discussions.