Addressing Personal Protective Equipment (PPE) Decontamination: Methylene Blue and Light Inactivates SARS-CoV-2 on N95 Respirators and Masks with Maintenance of Integrity and Fit

Background: The coronavirus disease 2019 (COVID-19) pandemic has resulted in severe shortages of personal protective equipment (PPE) necessary to protect front-line healthcare personnel. These shortages underscore the urgent need for simple, efficient, and inexpensive methods to decontaminate SARS-CoV-2-exposed PPE enabling safe reuse of masks and respirators. Efficient decontamination must be available not only in low-resourced settings, but also in well-resourced settings affected by PPE shortages. Methylene blue (MB) photochemical treatment, hitherto with many clinical applications including those used to inactivate virus in plasma, presents a novel approach for widely applicable PPE decontamination. Dry heat (DH) treatment is another potential low-cost decontamination method. Methods: MB and light (MBL) and DH treatments were used to inactivate coronavirus on respirator and mask material. We tested three N95 filtering facepiece respirators (FFRs), two medical masks (MMs), and one cloth community mask (CM). FFR/MM/CM materials were inoculated with SARS-CoV-2 (a Betacoronavirus), murine hepatitis virus (MHV) (a Betacoronavirus), or porcine respiratory coronavirus (PRCV) (an Alphacoronavirus), and treated with 10 M MB followed by 50,000 lux of broad-spectrum light or 12,500 lux of red light for 30 minutes, or with 75{degrees}C DH for 60 minutes. In parallel, we tested respirator and mask integrity using several standard methods and compared to the FDA-authorized vaporized hydrogen peroxide plus ozone (VHP+O3) decontamination method. Intact FFRs/MMs/CM were subjected to five cycles of decontamination (5CD) to assess integrity using International Standardization Organization (ISO), American Society for Testing and Materials (ASTM) International, National Institute for Occupational Safety and Health (NIOSH), and Occupational Safety and Health Administration (OSHA) test methods. Findings: Overall, MBL robustly and consistently inactivated all three coronaviruses with at least a 4-log reduction. DH yielded similar results, with the exception of MHV, which was only reduced by 2-log after treatment. FFR/MM integrity was maintained for 5 cycles of MBL or DH treatment, whereas one FFR failed after 5 cycles of VHP+O3. Baseline performance for the CM was variable, but reduction of integrity was minimal. Interpretation: Methylene blue with light and DH treatment decontaminated masks and respirators by inactivating three tested coronaviruses without compromising integrity through 5CD. MBL decontamination of masks is effective, low-cost and does not require specialized equipment, making it applicable in all-resource settings. These attractive features support the utilization and continued development of this novel PPE decontamination method.


INTRODUCTION
The coronavirus disease 2019  pandemic caused by SARS-CoV-2 has resulted in critical personal protective equipment (PPE) shortages, especially filtering facepiece respirators (FFRs, also known as N95 respirators) and medical masks (MMs). N95 FFRs are respiratory protective devices which are designed to filter at least 95% of airborne particles. A MM is a medical device covering the mouth, nose and chin ensuring a barrier that limits exposure of an infective agent between healthcare personnel (HCP) and the patient. MMs are used by HCPs to prevent large respiratory droplets and bodily fluid splashes from reaching the mouth and the nose of the wearer and help reduce and/or control at the source the spread of large respiratory droplets from the person wearing the mask. MMs include surgical and procedure masks and are not considered respiratory protective devices. N95 FFRs tightly fit the face while MMs are designed as loose-fitting devices. Although designed for single short-term usage, FFRs and MMs potentially contaminated by SARS-CoV-2 are being re-used on an emergency basis due to short supply during the current pandemic. These shortages have necessitated the rapid development and deployment of various disinfection techniques and equipment, and have led to the World Health Organization (WHO) issuing interim guidance on rational PPE use (1), including methods for decontamination (mostly for FFRs) (2). The U.S. Food and Drug Administration (FDA) granted Emergency Use Authorization (EUA) of hydrogen peroxide and steam sterilization systems to decontaminate FFRs/MMs intended for reuse (3). However, these technologies remain less available in low-resource settings, where the majority of frontline HCPs have inadequate protection.
Photochemical treatment represents a disinfection method that uses a photosensitive drug, referred to as a photosensitizer, which when combined with visible light, generates singlet oxygen from ambient molecular oxygen in the air. Singlet oxygen inactivates viruses by damaging viral nucleic acids and viral membranes (4,5). One such photosensitizer is methylene blue (MB), which, in addition to its primary FDA-approved medical indication to treat methemoglobinemia, has been used as a sterilization method for human plasma transfusions when combined with light, used for inactivating SARS-CoV-2 and many other microorganisms (6)(7)(8). See Supplemental material for additional background information.
The aim of the "Development of Methods for Masks and N95 Decontamination" (DeMaND) study was to evaluate methods that inactivate SARS-CoV-2 on respirators and masks, which can be applied anywhere, at low cost and without complicated procedures. We examined if methylene blue plus light (MBL) or dry heat (DH) treatments could effectively decontaminate commonly used FFRs, MMs, or a community mask (CM) while maintaining mask integrity (filtration, breathability, fluid resistance and fit) after multiple cycles of decontamination. This study leveraged four virology laboratories and six PPE integrity testing sites to examine: (a) MBL and DH virucidal effect using two isolates of SARS-CoV-2 and two other coronaviruses requiring a lower level of biocontainment, and (b) the impact of five cycles of decontamination (5CD) on the integrity of treated FFRs/MMs and a CM [FIGURE 1].
The number of decontamination cycles was selected based on the Centers for Disease Control and Prevention (CDC)'s recommended maximum number of donnings as part of crisis capacity strategies based on the current literature (9). The FFRs/MMs were selected based on popularity and availability during recent outbreak response and to account for physical differences such as cup shapes, material and structure. For the integrity testing, we compared MBL and DH to the FDA-authorized vaporized hydrogen peroxide plus ozone system (VHP+O3) (2).

FIGURE 1. Graphical representation of the DeMaND study outline. (A) Overview of the coronaviruses, decontamination methods and masks used. (B) FFRs, MMs andr a CM were inoculated with virus and treated with either MB and light (MBL) or dry heat (DH). Remaining infectious virus was quantified using TCID50 or plaque assays. (C)
In parallel with the virucidal testing of MBL and DH treatments, intact FFRs/MMs/CMs were subjected to 5 cycles of decontamination before mask integrity/fit was tested using the indicated methods. Abbreviations: PRCV = porcine respiratory coronavirus, SARS-CoV-2 = severe acute respiratory syndrome coronavirus 2, MHV = murine hepatitis virus, MBL = methylene blue + light, DH = dry heat (75°C), VHP+O3 = vaporized hydrogen peroxide plus ozone. See Supplemental Table S1 for the respirator and mask decontamination and testing matrix.

Methylene blue and light (MBL) inactivates coronaviruses in tissue culture plates
To confirm that MBL is able to inactivate coronavirus, varying concentrations of MB were mixed with porcine respiratory coronavirus (PRCV) and exposed to light (12,500 lux of red light). Treatment with 0.1 µM MB plus light resulted in a 6-log reduction in PRCV titers. In the absence of additional light, a higher MB dose (1 µM) still resulted in a 6-log reduction [FIGURE 2A].
Next, to confirm the ability of MBL to specifically reduce SARS-CoV-2 infectivity, varying concentrations of MB were mixed with SARS-CoV-2 and exposed to high intensity broadspectrum light (50,000 lux). MB inhibited SARS-CoV-2 infectivity with a dose-dependent effect, with or without exposure to high intensity light. This virucidal effect was strikingly enhanced in the presence of a strong light source. The half-maximal effective concentration (EC50) of MB was 3.1 µM when exposed to <100 lux of light, but 1.8 nM with the addition of high intensity light, a 1722-fold effect [FIGURE 2B].

FIGURE 2. Inactivation of PRCV and SARS-CoV-2 using methylene blue and light (MBL). (A)
To determine the efficacy of different MB concentrations, serial dilutions of MB were added to wells of a 48-well plate containing 10 µL PRCV (2x10 7 TCID50/ml). Technical triplicates were performed using three separate plates. Plates were either exposed to a red-light source (12,500 lux) for 30 minutes or were protected from light (<100 lux). Dotted line indicates limit of detection. (B) Serial dilutions of MB were added to wells of a 12-well plate containing ~50 PFU of SARS-CoV-2 in MEM plus 15% FCS. Plates were either exposed to 50,000 lux of broad-spectrum light for 45 min or were protected from light (<100 lux). Viral titers were determined using three replicate samples.

MBL and DH inactivate coronaviruses on FFR/MM material
To examine the dose required to inactivate respirators/masks contaminated with SARS-CoV-2 or murine hepatitis virus (MHV), we tested a representative generic facemask and N95 respirator (Type II generic facemask (FW) and 3M 1870+ N95 respirator (R3), respectively). These masks were cut into coupons, inoculated with virus, and treated with 1 or 10 μM MB and light for the indicated time periods [FIGURE 3A]. All viruses displayed sensitivity to MBL treatment. Using 10 µM MB with light resulted in complete inactivation of SARS-CoV-2 and MHV on both FFR and MM material after 5 minutes of treatment: a 3-4 log reduction of SARS-CoV-2 and >5 log reduction of MHV titers. Using a lower dose (1 µM), complete inactivation was observed after 30 minutes of light exposure, though a 2-4 log reduction of viral titers was already observed after 5 minutes. We also observed that MB treatment in the absence of additional light resulted in substantial reductions of viral titers.
In parallel, coupons inoculated with SARS-CoV-2 or MHV, or complete masks inoculated with PRCV, were treated with 65°C or 75°C dry heat (DH) for up to 60 minutes. Although all viruses displayed a degree of temperature sensitivity, 60 minutes exposure did not result in complete inactivation [FIGURE 3B]. . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint

FIGURE 3. MBL and DH inactivate MHV, SARS-CoV-2 and PRCV on FFR/MM material. (A) Effect of methylene blue and light treatment on SARS-CoV-2 and MHV titers. A 10 µl aliquot of SARS-CoV
The copyright holder for this this version posted December 11, 2020. ; To ensure that MBL or DH can be utilized to efficiently decontaminate a wide variety of masks, we tested 3 more masks, including one additional MM (Type IIR ASTM F2100 Level 2 Halyard (FH)), and two additional FFRs (duckbill FFR from Halyard (RH) and half-sphere 1860 from 3M (RM)). Coupons or intact masks were inoculated as described, treated with 10 µM MB and exposed to light for 30 minutes [FIGURE 4A-D], conditions which demonstrated robust inactivation in the previous experiments. We observed complete inactivation (up to 4 logs) of SARS-CoV-2 for all masks and respirators tested. Treatment with 10 µM MB without exposure to bright light resulted in substantial virus reduction [ FIGURE 4B]. For MHV, no virus was detectable for FH, R3, RH, and RM, signifying a 4-5 log reduction. A low level of virus was detectable in one replicate for FW [ FIGURE 4A]. For PRCV, which was injected underneath the outer mask layer, a >5-log virus reduction was observed after MB treatment of FH, FW, R3 and RH masks. In contrast, only an approximate 3-log reduction was observed for RM masks [ FIGURE 4D].
To assess DH inactivation of these additional 3 masks, coupons or intact masks were inoculated with virus and exposed to 75°C for 60 minutes. PRCV was generally effectively inactivated by DH treatment, resulting in >5 logs of virus reduction [FIGURE 4H]. FH and RM coupons inoculated with SARS-CoV-2 were not fully inactivated [FIGURE 4F,G]. MHV titers were only modestly reduced (~2 logs) across all mask types [FIGURE 4E]. Total log reductions for both MBL and DH conditions by mask type are listed in [TABLE 1].
In addition, we tested the effect of MBL or DH inactivation on MM and FFR straps inoculated with PRCV. MB and DH treatment of FH, FW, and R3 elastic straps resulted in inactivation of nearly 4 logs of PRCV. In contrast, MBL treatment of RH, as well as both MBL and DH treatment of RM respirator straps resulted in infectious titer reductions of less than 3 logs [Supplemental FIGURE S4].

Community Mask
Cloth community masks (CM) are globally in wide use; therefore, we investigated the decontamination efficacy of MBL and DH on a homemade CM made of a cotton inner and outer layers surrounding two layers of spunbond polypropylene.
Overall, virus recovery from the CM mask (made of cotton inner and outer layers surrounding two layers of spunbond polypropylene) was less efficient than from the FFRs and MMs, possibly due to absorption by the outer cotton layer. This was especially prominent for SARS-CoV-2inoculated CMs. MBL treatment of CMs resulted in complete inactivation of SARS-CoV-2 and MHV. In contrast, PRCV titers were only reduced by 0.4 log, whereas >5 logs of PRCV were inactivated after DH treatment [FIGURE 5A-D].
The overall percent reduction in virus titer after treatment across all FFRs/MMs and viruses ranged from 99.8-100% for MBL, and 96.9-99.6% for DH. For the CM this was 88.8% for MBL and 97.2% for DH [TABLE 1].

TABLE 1. Log reduction and percent inactivation of coronaviruses treated with MBL or DH.
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Evaluation of Potential Applications of MBL in a Clinical Setting
Three potential applications of MB in a clinical environment were examined. First, since some clinical settings may not have access to bright light, we investigated whether 10 µM MB combined with ambient light would be sufficient to inactivate SARS-CoV-2. Nearly 5-log of SARS-CoV-2 was inactivated by treatment with 10 µM MB and exposure to 700 lux (ambient light generated by light in a biosafety hood) for 60 minutes, and nearly 3-log of virus was inactivated by 10 µM MB in <100 lux of light (biosafety hood with the lights off) [ FIGURE 6A]. Second, the possibility of pre-treating respirators/masks with MB was investigated. Coupons were treated with 10 µM MB, dried, and inoculated with SARS-CoV-2 on either the hydrophobic outer layer or the hydrophilic inner layer before exposure to 50,000 lux of light for 30 min. No infectious virus could be recovered from either side of the light-exposed coupons, signifying inactivation of >4 logs of virus [ FIGURE 6B]. Intact RM respirators and FH masks were sprayed with 10 µM MB, dried overnight, inoculated with MHV, and exposed to 50,000 lux of light for 30 min. No detectable virus was recovered [ FIGURE 6D].
Lastly, 10 l of a sample from a clinical specimen (saliva) with a titer of 1.15 x 10 5 PFU/ml obtained from a COVID-19 patient was inoculated onto coupons from an R3 respirator and treated with MBL (30 min). No infectious virus was detectable after this treatment indicating that this inactivation method may be effective in a clinical setting where infectious virus may be found in proteinaceous matrixes which would potentially facilitate viability [ FIGURE 6C].
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FIGURE 6. Potential applications of MBL in a clinical setting. (A)
Effect of low light levels on SARS-CoV-2 inactivation using MB. A 10 µl aliquot of SARS-CoV-2 was applied to R3 coupons and dried for 20 min. Ten microliters of 10 µM MB was added to each coupon before treatment with 700 lux or <100 lux of light. Seven hundred lux is the light level produced by the biosafety hood lights and is used to represent ambient light. (B) Effect of MB pre-treatment on SARS-CoV-2 inactivation. Coupons were cut from R3 masks and soaked for 1 hr in 10 µM MB. The coupons were then air-dried in the dark for 2 days before adding 10 µl of virus to either the inner or outer layers. The samples were exposed to light (50,000 lux) for 30 min, and the virus titer determined by plaque assay using 6 replicates. (C) Inactivation of a SARS-CoV-2 clinical specimen by MBL. A saliva specimen was obtained from a COVID-19 patient with a titer of 1.1 x 10 5 PFU/ml for SARS-CoV-2. Ten µl aliquots were applied to coupons cut from a R3 mask and treated with 10 µM MB and exposed to 50,000 lux of light for 30 min. Each virus titer was measured using 6 replicate samples. (D) Effect of MB pre-treatment on MHV inactivation using intact masks. Intact R3 and FW masks were pretreated with 10 µM MB by spraying the front and back with a total of 7-8 ml of MB and allowed to dry overnight in the dark. The dried masks were inoculated with MHV and exposed to 50,000 lux of light for 30 minutes, and the inoculated areas were excised before elution and titration. ND = Not detected. FH= Type IIR Halyard face mask. RM= 3M 1860 half-sphere respirator. Dotted line indicates limit of detection.
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N95 Respirator, Medical Mask, and Community Mask Integrity Testing
Integrity of the FFRs/MMs/CM was assessed using a number of standard test methods to examine if MBL or DH decontamination treatments affected mask integrity. Filtration efficiency, breathability, fluid resistance and fit testing of FFRs/MMs/CM were assessed before and after 5CD. Results were compared to the FDA-authorized VHP+O3 decontamination method. The following sections describe each of the integrity test methods and results (see Supplemental  Tables S2A and S2B for all integrity test results). Certain test methods are employed for respirator approval/certification by the National Institute for Occupational Safety and Health (NIOSH) and European Notifying Bodies. Other tests, such as for medical masks, are required by the FDA for clearance or for compliance to the European Medical Device Directive.
First, we determined the filtration efficiency of the tested masks/respirators. Filtration efficiency testing measures the percentage of particles of a certain size that are stopped and retained by the mask material. Filtration efficiency testing using sub-micron (count median diameter of 0.075 ± 0.020 µm) sodium chloride (NaCl) particles is typically used to evaluate tight-fitting respirators, while medical masks are typically tested using larger 3-micron droplets containing culturable bacteria (Staphylococcus aureus). Sub-micron filtration efficiency testing is the more stringent of the two filtration tests since this method uses smaller and charge-neutralized particles, and a high air flow rate (simulating inhalation at heavy workload). Therefore, the standardized sub-micron testing was used to compare filtration efficiency between FFRs and MMs after decontamination treatments. Bacterial filtration efficiency was assessed only for MMs and CM. FIGURE 7A depicts the filtration efficiency of all FFR and MM models before (untreated) and after 5CD. High filtration efficiencies were expected for the FFRs as they were all NIOSHapproved N95 FFRs, which requires ≥95% sub-micron filtration efficiency. All three FFR models surpassed the minimum 95% NaCl sub-micron filtration efficiency requirement before and after 5CD. Untreated FW and FH masks achieved 76% and 86% filtration efficiency respectively, and in general filtration efficiency increased after MBL, DH, and VHP+O3 treatments for these masks. Since the CMs were made using materials found in the community, higher variability was observed between individual masks. As seen in FIGURE 7A, CMs achieved 34%, 32%, and 47% sub-micron filtration efficiencies at baseline (before treatment) and after MBL or DH treatments, respectively. Since VHP+O3 is not an effective decontamination method for materials containing cellulose, this treatment was not performed on CMs. Overall, MBL, DH, and VHP+O3 treatment of FFRs/MMs/CM did not cause any significant differences in the NaCl sub-micron filtration efficiency of the studied models (p>0.01).

Sub-micron Particulate Filtration Efficiency
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FIGURE 7. Effect of MBL, DH, and VHP+O3 treatments on the filtration efficiency of FFRs/MMs/CM. (A) NaCl sub-micron filtration efficiencies of FFRs/MMs/CM before and after 5CD. NaCl sub-micron filtration
efficiency is a measure of the ability of a respirator or medical mask to capture aerosolized particles smaller than one micron, expressed as a percentage of particles that do not pass the material at a given velocity or flow rate. Particle size ranges from 0.022-0.259 µm with a count median diameter of 0.075 ± 0.020 µm and a geometric standard deviation (GSD) of less than 1.86 to give a mass median aerodynamic diameter of 0. 3

Bacterial Filtration Efficiency (BFE) using 3-micron Droplets Containing Bacteria
Filtration efficiency of medical/surgical mask material is determined using bacterial filtration efficiency (BFE) testing. BFE should be ≥98% according to EN 14683 for Type II and ASTM F2100 for Level 2 medical masks. Both FW and FH masks achieved greater than 98% BFE before and after 5CD of the three different decontamination methods while CM achieved 88%, 91%, and 87% BFE as baseline and after MBL and DH treatments, respectively [ FIGURE 7B]. Overall, no significant differences were observed in the BFE values of any of the tested mask models after 5CD with the three decontamination treatments.

Breathability Testing
The breathability, or resistance to airflow via inhalation and exhalation, is an indication of the difficulty in breathing through the respirators or masks. Breathability is an important property for FFRs' and MMs' wearer comfort. The breathability of FFRs is assessed by inhalation and exhalation resistance tests. According to 42 CFR Part 84 requirements, exhalation resistance should not exceed 25mm H2O and inhalation resistance should not exceed and 35 mm H2O. EN 149 also requires that the inhalation resistance of respirators (FFP2) at slightly higher flow rate (95 L/min) should be less than 2.4 mbar, or approximately 24 mmH2O. Breathability of MMs is determined by a differential pressure test, which is one of the requirements according to ASTM NP NP . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint F2100-19 and EN 14683:2019 medical face mask standards. It is also one of the required test methods by FDA for clearance of certain medical masks, including surgical masks. FIGURE 8A and 8B show inhalation and exhalation resistances of FFRs/MMs/CM before and after 5CD. Results show that all FFR models achieved inhalation and exhalation resistance far below the breathing resistance limits according to applicable standards and regulations, implying that it would not be harder for the wearer to breath through the masks after 5 decontamination cycles. Although assessments of inhalation and exhalation resistance is not commonly conducted on MM materials, these properties were assessed in this study to understand the impact of decontamination processes on MMs, and to compare FFRs with MMs in terms of breathability. MMs demonstrated similar inhalation resistances, but much lower exhalation resistance values compared to FFRs. Inhalation and exhalation breathing resistances were at least 60% below the allowable thresholds for all FFR models, according to the respective NIOSH 42 CFR Part 84 and EN 149 requirements for breathing resistance of FFRs. Inhalation resistance of all face masks decreased (improved) after 5CD. Notably, inhalation resistance of the CM declined from 8.1 to 4.2 and 3.4 mmH2O after MBL and DH treatment, respectively.

Differential Pressure
The differential pressure (pressure drop) test measures the differential air pressure on either side of the MM materials using a digital manometer and is a required test method according to ASTM F2100-19 and EN 14683:2019. It is also one of the required test methods by FDA and the European Medical Device Directive for clearance of medical masks. As shown in FIGURE 8C, all of the MMs/CM maintained performance below the maximum allowed differential pressure values before and after 5CD. A slightly higher pressure drop was noted after decontamination with VHP+O3 for both MMs. Overall, no concerns were reported in terms of breathability after the decontamination treatments. An additional, modified breathability test was performed using a Sheffield dummy that simulated breathing and wear, see Supplemental Figure S5.
. CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; Fluid Resistance Testing During a medical procedure, a blood vessel is occasionally punctured resulting in a high velocity stream of blood impacting a medical face mask. Fluid (splash) resistance testing is used to evaluate the resistance of medical face masks to penetration by a small volume (~2 mL) of a high-velocity stream of synthetic blood. Medical face mask pass/fail determinations are based on visual detection of synthetic blood penetration on the reverse side. Fluid resistance properties of . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint

Figure 8. Effect of MBL, DH, and VHP+O3 treatments on the breathability of FFRs/MMs/CM. (A) Inhalation and (B) Exhalation breathing resistances before and after 5CD. The resistance to airflow during inhalation and exhalation is an indication of the difficulty in breathing through the respirators/masks. (C)
The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint MMs and CM were assessed by both challenging from the inside (inner surface) to investigate their potential source control performance, and from the outside (outer surface) to investigate the protection from splash and sprays that can be encountered during surgeries, patient care, and large droplets (respiratory secretions) that may be generated by other people's coughs or sneezes.
FW masks demonstrated 60% pass before treatment, and 80%, 50%, and 40% pass when challenged from inside (observed outside) after MBL, DH, and VHP+O3 treatments, respectively [FIGURE 9]. Untreated and DH-treated FH masks achieved 90% pass when challenged from the inside. The passing results increased to 100% after MBL or VHP+O3 treatments. In addition, untreated, MBL and DH-treated CMs demonstrated 30%, 40% and 50% pass rates respectively, when challenged from inside (observed outside). The fluid resistance of CMs was higher when challenged from the outside compared to the inside. This result was unexpected since the same fabric types were used in the inner and outer surfaces of the CM. However, it may be from the variable and uncontrolled nature of the construction of community masks. Furthermore, it was observed that the decontamination processes increased the fluid resistance of outside materials of both MM models. However, fluid resistance of outside materials of CMs declined after MBL and DH treatments. There were no significant differences between treated masks and untreated masks (Fisher's exact test).

Fit Testing
The respirator must fit the user's face snugly (i.e., create a seal) to minimize the number of particles that bypass the filter through gaps between the user's skin and the respirator seal. Therefore, fit testing is a critical component to a respiratory protection program whenever workers use tight-fitting respirators, such as N95 FFRs. Fit testing provides a measure of how well a respirator/mask seals around the contours of the face. A good fit ensures exchanged air is filtered through the respirator/mask. Fit was assessed using a PortaCount ® PRO+ 8038 machine with human participants (many of whom were healthcare personnel), and their natural is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; anthropometric variations. In addition, advanced headforms that mimicked human head shapes were used to measure fit. The impact of the decontamination method on respirator/mask fit, in terms of fit factors (FF) was compared. Strap/ear loop/tie elastic recovery/tensile strength testing was also performed to investigate discrepancies in fit.
Respirators maintained human participant FF values above 100 after 5 MBL and DH decontamination cycles. However, five cycles of VHP+O3 decontamination decreased human fit of RH and RM to the point of failure [FIGURE 10A]. Human fit testing was also performed for MMs and CMs to demonstrate that these types of masks are not designed to ensure a tight fit [ FIGURE 10A].
A 'strong acrid odor' was noted on some of the VHP+O3 treated FFRs and MMs, while 'not unpleasant slight odor' was noted on some of the FFR after MBL and DH treatments at one of the fit testing sites. Partial elasticity loss in the VHP+O3 treated FFR straps and MMs ear loops were also observed by the wearers, see Supplemental section: Tensile Testing of Elastomeric Straps, Ear Loops, and Ties. Some of the nosepiece foams on VHP+O3 treated RMs were discolored (turned from gray to brown). In addition to the discoloration, the nose bridge was more rigid for the three MBL-treated RMs.
Manikin fit factors using an advanced, realistic manikin head, resulted in similar overall passing of the OSHA 1910.134(f)(10) criterion of 100 FF for all three FFRs (11) [FIGURE 10B]. The differences observed between human fit and manikin fit can be attributed to the variability in testing procedures and human facial dimensions and generally the challenge of FFRs to universally fit the wearer.
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DISCUSSION
We observed that methylene blue and light applied to FFR and MM completely inactivates SARS-CoV-2. Importantly, MBL, as a new proposed decontamination method, did not cause any significant changes in any of the filtration, breathability or fluid resistance properties investigated in this study after 5 decontamination cycles, and our results are consistent with filtration efficiency seen after VHP+O3 treatment. The additional finding that MB-pretreated FFRs and MMs continue to inactivate coronavirus provides a potential opportunity for healthcare providers and other front-line workers to safely re-use their PPE, as well as supply active viral inactivation during wear. MB is available globally and can be applied using spray bottles. This study demonstrates viral inactivation using MB combined with 50,000 lux of broad-spectrum light (~1/3 of illumination on a sunny day). Bright light treatment can be supplied by simple white light lamps sold in hardware stores. Furthermore, in a small preliminary experiment, even MB exposed to ambient light (700 lux) and low light (<100 lux) inactivated SARS-CoV-2. This finding needs to be further studied but suggests that MB can work using ambient light available in hospital and clinic settings. We did observe, however, that lower light intensities require a longer light exposure duration for efficacy.
Identifying methods to decontaminate PPE to protect healthcare personnel is paramount. A recent study demonstrated recovery of viable virus from FFR material inoculated with viral loads of SARS-CoV-2 and stored at 20°C with 40-50% relative humidity for 21 days. (12) These common conditions in health care settings demonstrate the importance of having an inexpensive, simple, and robust means of decontamination of PPE like MBL that can retain functionality and performance. In our study, PRCV was inoculated under the outer layer of MMs and FFRs to mimic the worst-case scenario of high-titer virus penetrating the outer layer of a mask. MBL robustly inactivated >5 logs of virus for both MMs and 2 of the FFRs, suggesting that both MB and light were able to sufficiently penetrate the outer layer of the PPE. The exceptions were RM (2.7 log or 99.8% reduction) and CM (0.4 log or 60.5% reduction). RM is a half-sphere with a more rigid shell which may have blocked some of the MB or light from penetrating to the inner layer. Fisher et al. saw a similar finding with UVC light penetration, which was impacted the further into the filter material the light passed. (13) Consistent with previous studies (14), the DH and VHP+O3 treatments did not alter the filtration efficiency of masks and respirators tested in this study. MB and the DH decontamination can now be added to the rare category of decontamination methods that do not violate mask integrity for the models tested (including fit), which thus far only included the gold standard VHP (3,9,14-16-). Although the FDA approved a few VHP systems for PPE decontamination, they are not easily obtainable in low-resource settings. Various studies have also investigated the impact of . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity.

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The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint heat on the filtration efficiency and physical deformation of FFR or filter media and demonstrated that higher temperatures could negatively affect integrity (13,17,18).
Dry heat yielded inconsistent viral inactivation in our study possibly owing to evidence that humidity plays a role in heat inactivation (19). The finding that DH on CM materials yielded better viral inactivation may be due to the ability of the cotton materials to rise to inactivationlevel temperatures faster than the synthetic FFR and MM materials, although we did not test the material surface temperature during the heating to prove this. In one study, improved inactivation was demonstrated with moist heat (100% relative humidity) reducing initial SARS-CoV-2 titers almost 5-logs at 75C for 30 minutes (19). Our rationale for testing 75C DH without humidity related to testing the simplest method which could be replicated in any location where standard ovens exist without the complexity of regulating or delivering a certain amount of humidity.
We decided to compare a CM in this study to provide first definitive analysis in the same study format used for respirators and medical-grade masks. The tested CM performed surprisingly well in some of the integrity tests. This is likely due to the double cotton layer combined with two layers of polypropylene spunbond fabric. Not all CMs in use around the world contain these multiple layers, especially non-woven layers. The heterogeneity of materials and design, and lack of standardization of CM used for source control make generalized conclusions difficult. When testing MBL virucidal activity on CM, we observed inconsistent results when virus was inoculated under the cloth layer. This could be due to absorption of MB into the cotton layer. Alternatively, CM material color or finishing dye chemicals potentially impeded MB efficacy through light absorption. These hypotheses should be tested using alternative CM fabrics, colors, and models.
Our studies on MBL, DH, and VHP+O3 decontamination were constructed to parallel other studies investigating the impact of heat and VHP+O3 on the filtration efficiency and physical deformation of FFR or filter media. Previous studies evaluated meltblown polypropylene filter media using NaCl aerosol testing and found that filtration efficiency remained ≥95% after twenty treatment cycles consisting of 75°C for 30 min (14,17,20). On the other hand, Viscusi et al. (15) autoclaved two FFR models at 121°C/15 psi for 15 or 30 minutes and reported that filtration efficiency of both models decreased below minimum NIOSH requirements. A study investigating dry heat at lower temperature settings (110°C) reported that reduction of filtration efficiency was FFR model-specific (16). Previous studies also reported that VHP did not result in the reduction in the filtration efficiency of any of the N95 FFR models tested, while showing significant inactivation of spores, bacteriophages, and SARS-CoV-2 virus (3,9,14,16,20). Battelle CCDS (Critical Care Decontamination System)™ was approved by the FDA as the first emergency use authorization (EUA) for decontamination system for FFRs (3). In Battelle's system, the 3M 1860 model (RM) was shown to maintain filtration performance for 50 treatment cycles of VHP treatment using the Clarus® R HPV generator (utilizing 30% H2O2) (3). Additionally, FFR fit was shown to be unaffected for up to twenty VHP treatments cycles using a manikin headform which was assessed on one FFR model without donning and doffing between cycles.Strap degradation, however, did occur after twenty treatment cycles (3). In addition, the FDA has issued an EUA for the SSS VHP N95 Respirator Decontamination System manufactured by Stryker Sustainability Solutions where reprocessing is limited to three cycles (2).
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The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint Fischer et al. (14) incorporated test subject quantitative respirator fit testing of intact FFRs using a PortaCount® following each cycle of heat treatment and wear for two hours and reported that the mean fit factor of six fit tests remained >100 for both one and two treatment cycles, but fell slightly below 100 after three dry heat (70°C) cycles. They also reported that one FFR did not have any physical deformation. The same study reported that the mean fit factor of six fit tests remained acceptable (according to OSHA criterion) following three VHP treatment cycles.
We also collected additional measures related to the physical appearance, physical comfort, and user acceptance of decontaminated FFRs/MMs. The purpose of these measures was to determine whether different decontamination methods impact FFRs and MMs in ways beyond physical fit, which could affect perceptions of healthcare personnel in terms of their use of decontaminated devices and ultimately if the use of decontaminated devices would affect HCPs' performance and delivery of care. We plan to analyze and report upon this component of the study in a future publication.
There were limitations to this study. We only tested 3 types of FFRs, yet there are approximately 500 N95 FFR models approved by NIOSH and many medical masks around the world. Each FFR, MM, or CM model has distinct filter/strap/ear loop/tie materials and design characteristics (e.g., surface area, dead space, nose padding). The differences in materials and design characteristics among all available FFR/MM/CM models result in variable outcomes for decontamination efficacy and effect of decontamination on FFR performance. CDC recommends that a decontamination method's effectiveness be evaluated for specific FFR models in collaboration with the manufacturer, and if needed, a third-party laboratory (21).
Another limitation within our study was that our primary inactivation studies were performed with direct application of a fixed quantity of MB onto coupons and only two of our experiments tested the spraying of MB onto a whole mask or the soaking of PPE material into a solution of MB. We attempted to normalize the volume of MB applied to the coupons to the amount of per square surface area. For example, if 7-8 mL of MB solution was sprayed onto an intact mask (4 sprays on outer and 2 sprays on inner surface), based on the surface area of a 3M N95 1860 respirator (RM), this would result in 10-30 ul of MB for the each 1 cm 2 coupon.
In our clinical specimen experiment, we demonstrated SARS-CoV-2 inactivation with MBL. Obtaining whole masks worn by healthcare personnel who cared for COVID-19 patients was not in the scope of our study, yet would add strength to our finding that a saliva specimen from a COVID-19 positive patient was inactivated by the MBL treatment.
All labs performed their studies with 'biological triplicates'three like-masks or respirators from the same respective manufacturing batches were used for every mask tested. We attempted to enhance and strengthen our findings by leveraging four different virology testing sites using three different coronavirus species, including two surrogate coronaviruses. Our findings with the surrogate coronaviruses allow future studies to test diagnostics and therapeutics at lower levels of biocontainment than required for SARS-CoV-2. We believe that conducting our simultaneous experiments across two continents using the same methodology but in different labs, as well as conducting additional experiments using a SARS-CoV-2 clinical sample provides generalizable knowledge. The heterogeneity of light administration methods replicated practical light scenarios. The ovens used in the studies were all different and only standardized for the . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity.

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The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint temperature administered (75°C). The use of alternative heat and alternative light producing methods parallels what we would expect in the real-world settingsno standard products, but ability to standardize a protocol.
The biocompatibility of MB on masks was not tested in this study yet the concentrations of MB -10 Mused to spray onto the masks or used to drop onto mask coupons, were far below the clinically used MB concentrations administered intravenously for methemoglobinemia (1 mg/kg) (5), orally as third line therapy for malaria (22), or applied intranasally for Staphylococcus aureus (23). The amount of MB sprayed onto each mask using our 10 µM solution was <0.026 mg. Our team will be testing the amount of MB that a wearer might inhale during the course of an 8-10 hr shift wearing a mask. Although human fit testers of the MBL-treated masks did not experience any negative effects, more rigorous inhalational biocompatibility tests need to be done.
We did not replicate multiple real-life PPE donning and doffing over multiple shifts or extended wear which could affect FFR fit and performance over time. Degesys et al. tested the real time fit using models we used in our study. The 3M 1860 maintained fit for more than 5 donnings (24). In addition, off-gassing of decontamination chemicals was not evaluated although anecdotally, some wearers of the VHP+O3 treated masks complained of an "acrid" or "acidic" smell while some wearers of the MBL-treated masked claimed that there was a "mild" and "calming" aroma appreciated. Human factors assessments, including user acceptance of decontaminated FFRs, MMs, and CMs by HCPs are underway. Further testing of the MBL method for user acceptance and workplace compatibility are also being explored.
We demonstrate that MB activated by broad-spectrum white or red light effectively inactivates coronaviruses including the novel SARS-CoV-2 on typical medical mask surfaces without affecting mask material integrity, or alterating mask fit and filtration characteristics. This series of studies provides evidence that MB can be applied to the surface of a FFR or MM and illuminated by a light source as a disinfection technique, enabling safer reuse of single-use disposable respirators and masks in shortage situations. One could envision using this decontamination process after each work shift in a healthcare setting. Integrity was maintained for the FFR models tested in this study after 5CD, however, the variability in the the design and materials (e.g., straps and earloops) may still lead to mask performance changes with successive donnings and doffings that will still need to be assessed to ensure adequate fit of the respirators. Residual MB remaining on the mask surface activated by ambient white light could also provide a novel means of continual disinfection of viral particles which become adherent to the mask surface in-use. Indeed, under ambient lighting condition, the surface of the masks treated with MB could produce up to 3.2x10 15 molecules of singlet oxygen per second (Supplemental Table  S6). Other potential uses include application of MB to face coverings used in low resource medical and general community settings, in order to enhance protection, not only of persons in proximity to the face covering user, but also to increase protection of the user from airborne virus. In the medical setting, on site, MBL spot treatments of PPE touch points prior to doffing may also decrease accidental contamination and may potentially provide increased protection of healthcare and laboratory workers. A further series of experiments intended to support the implementation of these additional uses of MB and light are underway.
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CONCLUSION
We provide the first evidence that methylene blue and light can inactivate human coronavirus on FFRs and MMs commonly worn by healthcare personnel and essential workers without decreasing performance and fit. Our findings provide a recipe for easily accessible, inexpensive, effective PPE re-use and afford an opportunity for utilization in high-and low-resourced settings to address issues of global supply shortages and reduced time of decontamination relative to VHP+03. Residual MB remaining on the mask surface activated by ambient white light could also provide a novel means of continual disinfection of viral particles which become adherent to the mask surface in-use, continually reducing wearer exposure to SARS-CoV-2. We are investigating applying MBL to a wider range of high-threat pathogens.  Table S1 for details on which labs and testing sites respirators and masks were sent to for decontamination and testing.

TABLE 2. Masks and Respirators used in this study.
Viruses SARS-CoV-2 was obtained from Dr. Darryl Falzarano (VIDO) (GISAID accession ID: EPI_ISL_425177) used in Lab 2 or from a patient at the George Washington University Hospital used in Lab 1 and was propagated in Vero CCL-81 cells. Viral titers were determined by plaque assay and typically reached 1.0-6.6 x10 6 PFU/mL. A SARS-CoV-2 clinical saliva specimen with a titer of 1.1 x 10 5 PFU/ml was obtained with the University of Calgary Conjoint Health Research Ethics Board approval (ID# REB20-0444). The recombinant murine hepatitis virus (MHV) stock (rA59-E-FL-M) was described previously (25). Porcine respiratory coronavirus (PRCV), a spike gene deletion mutant of transmissible gastroenteritis virus (TGEV) and a member of the Alphacoronavirus 1 species (26,27), was used as a SARS-CoV-2 surrogate.

Light Sources for Methylene Blue Testing
Light boxes developed at Colorado State University were used at Seattle Children's Research Institute, George Washington University, University of Calgary and Nelson Laboratories containing the 4000K Husky LED lights (model# K40187). Husky LEDs were also used at the University of Alberta but were 3500K. The University of Liège and Centexbel used a light box of their own design containing horticultural lamps for their studies. Luminescence was verified using light meters in all laboratories (Latnex, model LM-50KL; DeltaOHM, Model HD2102.2; or Cooke, Model CK-CL400; see Supplemental section).

Virus Inoculation and Elution
Masks were cut into 7-10 mm 2 coupons and inoculated with the maximum available titer of SARS-CoV-2 or the surrogate coronaviruses (MHV or PRCV). The volume of the inoculum for SARS-CoV-2 and MHV was 10 L. Virus was added to the outer layer of each coupon (or inner layer where specified) with a pipette and dried for 20 mins before inactivation treatments were initiated. For elution, coupons were soaked in media in a 1.5 ml microtube (MHV, SARS-CoV-2 experiments) or 15-ml tube (PRCV experiments). Tubes were vortexed or rocked on an orbital rocker for 10-20 minutes. Alternatively, 100 l PRCV was injected under the respirators/masks outer layer using an ultra-fine insulin needle. After decontamination, 34 mm 2 coupons were cut from the masks, placed in a 15-ml tube containing media and vortexed. Remaining infectious virus was quantified by median tissue culture infectious dose (TCID50)or plaque assays.

Methylene Blue Treatment
MB was obtained from Sigma (M9140), ThermoFisher Scientific (J60823) or American Regent (0517-0374-05). Stock solutions were prepared using ultrapure distilled water. After inoculation of the virus and a 20 min drying step, 10-30 l of MB at the indicated concentrations was added to the coupons and exposed to 50,000 lux of broad-spectrum light or 12,500 lux of red light for varying time points. Broad-spectrum light and red-light sources were based on the local labs' method for administering adequate light energy for MB activation. And 12,500lux of red light roughly equates to the same amount of light energy within the MB excitation wavelength that 50,000 lux of white light yields. Intact inoculated masks were sprayed with 7-8 ml of 10 M MB and allowed to dry for 30 minutes protected from light before exposure to 12,500 lux of red light . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint for 30 min. For dark control, coupons and masks were left in biosafety hood with the light off or covered by aluminum foil (<100 lux).
For the pre-treatment tests, R3 coupons were soaked with 10 µM MB for >1 hour and dried 2 days protected from light. SARS-CoV-2 was spotted on outer or inner mask layers, dried for 20 minutes before exposure to 50,000 lux of light for 30 min. Virus was eluted from the coupons and quantified by plaque assay. Intact RM and FW received 6 sprays on the front and 2 in the back (8 ml total) and dried overnight. MHV was added to three points on the outer surface, dried for 20 minutes and exposed to 50,000 lux of light for 30 min. The inoculated areas were excised from the mask, eluted, and quantified by TCID50 assay.

Dry Heat Treatment
Inoculated coupons were placed in a tissue culture plate and incubated at the indicated temperatures in a dry heat oven (IsoTemp, Fisher Scientific, VWR Dry-Line 56-Prime oven or Lab-line L-C oven with a DataChart 1250 temperature probe). A calibrated analog thermometer was used to verify temperature if a temperature probe was not available. Intact inoculated FFRs and MMs were placed horizontally on a metal frame in a dry oven (M-Steryl, AMB Ecosteryl Company) containing two calibrated Pt100 sensors to record the temperature throughout the experiment to ensure correct exposure conditions.

PPE Integrity Testing
Samples were tested as-received ('untreated'), with DH, with VHP+O3 and with MBL. All decontaminated samples were treated off-site (Nelson, 4CAir, University of Liege) before reaching the integrity labs for testing.

Filtration Efficiency Testing
Filtration was assessed using NaCl sub-micron particles for FFRs, MMs, and CM; and using 3micron droplets that contain bacterial challenge for MMs and CM. Although medical face masks are not typically tested using NaCl sub-micron particles, performing the tests with this challenging-size particle allowed comparison of filtration performance between masks and respirators. Sub-micron particulate filtration efficiency is a measure of the ability of a respirator or medical mask to capture aerosolized particles smaller than one micron, expressed as a percentage of a known number of particles that do not pass the material at a given face velocity for flat samples or flowrate for whole article testing. Untreated and decontaminated respirators were tested for filtration efficiency using a modified version of the NIOSH Standard Test Procedure (STP) TEB-APR-STP-0059 (29), using an Automated Filter Tester (CERTITEST®, Model 8130, TSI, Inc.) and according to the National Personal Protective Technology Laboratory (NPPTL) Decontaminated Respirator Assessment Plan (11). In sub-micron testing, charged-neutralized particle size ranges from 0.022-0.259 µm with a count median diameter of 0.075 ± 0.020 µm and a geometric standard deviation (GSD) of less than 1.86 to give a mass median aerodynamic diameter of 0.3 μm, and air flow is 85 L/min (which simulates inhalation at heavy workload). Respirator testing was completed at the NIOSH NPPTL. Results were evaluated against NIOSH performance criteria according to 42 CFR Part 84 for FFR approvals (minimum 95% filtration efficiency) (30). Untreated and decontaminated medical face masks and community masks were also tested following the same method at Nelson Laboratories.
. CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; The bacterial filtration efficiency (BFE) test is a conventional method to measure filtration efficiency of medical face masks (31). BFE was measured using the bacteria Staphylococcus aureus (diameter: 1 μm) as the challenge organism. A suspension of S. aureus was aerosolized using a nebulizer to give a challenge level of 1700-3000 colony-forming units (CFU) per test as specified by the ASTM F2101 method (32). The bacterial aerosol is a water droplet containing the bacteria and not an individual bacterial particle. The particles were not charge neutralized for testing. The aerosol sample was drawn through a test sample clamped into the top of a 6-stage Andersen sampler with agar plates for collection of the bacteria particles at a flow rate of 28.3 L/min for 1 min. The design of 6-stage Andersen sampler is based on the human respiratory tract, where all airborne particles greater than 0.65 μm are classified aerodynamically. The flow rate of 28.3 L/min is similar to human breathing flow rate (at light workload) to obtain deposition of particles in different stages of the Andersen sampler. Aerosol droplets generated in this test ranges from 0.65 to 7 µm with a mean particle size of approximately 3.0 µm. As previously mentioned, BFE was employed on masks only. It was performed on untreated and decontaminated MMs and CMs at Nelson Laboratories and Centexbel. Results were evaluated against performance criteria according to EN 148683 Type II and ASTM F2100 and Level 2 medical masks (≥98% 3 µm bacterial droplet filtration efficiency), CEN CWA 17553 (≥70% and ≥90% 3-micron solid or liquid particles without biological challenge) (33) and AATCC M14 (20) (>70% 3-micron latex spheres) for CM.
The filtration efficiency of fibrous filter materials is controlled by factors including, aerosol charge, particle size distribution, face velocity and filter material charge. When NIOSH submicron and BFE test methods are compared, NIOSH approval testing is considered as more stringent or worst-case method, because of the use of charge neutralized aerosol size close to the most penetrating particle size at relatively higher flow rate (face velocity), to produce maximum penetration or conservative filtration efficiency.

Breathability Testing
Breathability was assessed using inhalation and exhalation breathing resistance measurements according to the NIOSH standard testing procedures according to 42CFR Part 84 for the all of the respirators and masks (30, 34) and pressure drop measurements for masks only (ASTM F2100 and EN 14683). An additional breathability assessment using clause 7.16 of the EN 149 standard for European respirators was used and is termed "Sheffield Dummy Air Flow Differences" or Sheffield AFD (EN 149).
Inhalation and exhalation resistance of devices were tested using NIOSH STPs (TEB-APR-STP-0007 and TEB-APR-STP-0003). The results in mmH2O were recorded and evaluated against NIOSH performance maximum limits for FFR approvals (25 mmH2O for exhalation and 35 mmH2O for inhalation) at approximately 85 ± 2 L/min airflow. Respirator testing was completed at the NIOSH NPPTL while MMs and CMs were tested at the Nelson Laboratories.
The differential pressure (delta p) testing of untreated and decontaminated samples was performed according to ASTM F2100 and EN 14683 and measured the differential air pressure on either side of the mask using a digital manometer at Nelson Laboratories and Centexbel Laboratories. The delta p values were reported in mm water/cm 2 (required units for ASTM F2100) and Pa/cm 2 (required units for EN 14683) of test area and evaluated against ASTM . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint The copyright holder for this this version posted December 11, 2020. ; https://doi.org/10.1101/2020.12.11.20236919 doi: medRxiv preprint F2100 Level 2 and EN 14683 Type II requirements for and masks (ASTM F2100 <6.0 mm H2O/cm 2 and <40Pa/cm 2 for Type II).

Fluid Resistance Testing
Testing the fluid penetration resistance (resistance to splash and spray) by synthetic blood is one of the requirements of FDA surgical mask clearance in the U.S. for all three different levels of masks defined in ASTM F2100. It is also required by EN 14683 for Type IIR masks only. The synthetic blood penetration testing of untreated and decontaminated samples was performed on medical face masks and community masks at Nelson Laboratories and Centexbel according to ASTM F1862 or ISO 22609:2004 at 120 mmHg pressure which is required for ASTM F2100 Level 2 masks and EN 14683 Type IIR masks. For each mask type, five samples were tested with the outside facing the synthetic blood to determine the barrier resistance and five samples were tested with the inside facing the synthetic blood to assess the source control properties. The percentage of passing samples (no visible penetration) was calculated and compared to ASTM F2100 requirements (29 out of the 32 passing results).

Fit Testing Human Fit
Fit testing was conducted with the PortaCount® Pro+ 8038 (TSI Inc., Shoreview, MN, USA) at two study sites: Stanford University, and the University of Calgary. The human fit testing was determined to be exempt from ethics board review by both the Research Compliance Office, Stanford University (March 23, 2020) and the Conjoint Health Research Ethic Board, University of Calgary (June 12, 2020). All fit testing of masks was done with OSHA-approved protocols for testing N95. However, sample sizes and study designs differed between sites. At Stanford University, fit testing of test masks was performed on a human model (LC) using the OSHA test protocol of the PortaCount Pro+ 8038. At the University of Calgary, three groups of five healthcare personnel completed fit tests a repeated-measures design, with respirator type and between-subjects factor. At both sites, the fit test protocol consisted of eight dynamic tasks: normal breathing, heavy breathing, turning head side-to-side, head up-and-down, talking, grimace, bend over and normal breathing. Each cycle of tests was performed twice for each mask and Fit Factor (FF) was calculated.
In addition to these measures, participants at the University of Calgary (including 15 additional healthcare personnel who participated in a separate study arm focused on surgical/procedural and cloth masks; total N = 30) provided data on measures related to the physical appearance, physical comfort, and trustworthiness and acceptance of the decontaminated masks. Data from these measures, which is not included in the current manuscript, will be presented in a separate publication.

Manikin Fit
The static advanced headform fit testing (29) was used to determine the anticipated changes in fit. Static fit testing was completed on FFRs only at NIOSH NPPTL using a static advanced headform (StAH) that quantifies the changes in manikin fit factor. The TSI, Inc. PortaCount® PRO+ 8038 (Shorewood, Minnesota, USA) in "N95 Enabled" mode was used for this evaluation. Assessments of respirators were done using normal and deep breathing without dynamic movements and a speaking passage (11).
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Statistical Analysis
Measurements with standard error bars were generated using Prisma Analytics (Munich, Germany). Means and standard deviations or percent pass of each integrity test method were calculated separately by FFR/MM/CM style. Data for each integrity test method conducted at more than one test site were pooled to create overall means and standard deviations or percent pass. Normality of the data distribution was tested using the Shapiro-Wilk test. Significant differences between untreated and treated FFR/MM/CM were calculated with Student's t-tests, Mann-Whitney U tests, or Fisher's exact tests, as appropriate (SAS v9.4). EC50s were calculated using GraphPad Prism 8. Full results of integrity tests are presented in Supplemental Table S2A and 2B.
YC coordinated mask and respirator particulate testing by LL and MZ. MML provided the statistical analysis of the study data with assistance by PF for the PortaCount data at the Calgary site. The PortaCount human fit testing for the decontaminated masks at the Calgary site was planned by JMD, KP and SS and coordinated by RJM and JMC with assistance from SR, PF, and KH. AP and LFC provided PortaCount human fit testing data from the (Anesthesia Informatics and Media) AIM lab site. MCC, KH, ML coordinated the DeMaND study administration and logistics. All authors were provided the final manuscript for comments and approval. is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) preprint

SUPPLEMENTAL FIGURES AND TABLES
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