* These authors contributed equally
In response to the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic, a laboratory protocol was developed to test the viral disinfection efficacy of hot water laundering of cloth face coverings, cotton scrubs, and denim pants. The Phi6 virus (bacteriophage) was used as the organism to test disinfection efficacy.
This protocol provides an example of a laboratory process for conducting laundering studies that generate data on viral disinfection. While the protocol was developed for research during the coronavirus disease 2019 (COVID-19) pandemic, it is intended to be a framework, adaptable to other virus disinfection studies; it demonstrates the steps for preparing the test virus, inoculating the test material, assessing visual and integrity changes to the washed items due to the laundering process, and quantifying the reduction in viral load. Additionally, the protocol outlines the necessary quality control samples for ensuring the experiments are not biased by contamination and measurements/observations that should be recorded to track the material integrity of the personal protective equipment (PPE) items after multiple laundering cycles. The representative results presented with the protocol use the Phi6 bacteriophage inoculated onto cotton scrub, denim, and cotton face-covering materials and indicate that the hot water laundering and drying process achieved over a 3-log (99.9%) reduction in viral load for all samples (a 3-log reduction is the disinfectant performance metric in U.S. Environmental Protection Agency's Product Performance Test Guideline 810.2200). The reduction in viral load was uniform across different locations on the PPE items. The results of this viral disinfection efficacy testing protocol should help the scientific community explore the effectiveness of home laundering for other types of test viruses and laundering procedures.
The coronavirus disease 2019 (COVID-19) pandemic caused unprecedented global supply chain disruption and led to a critical shortage of many items, including essential personal protective equipment (PPE)1,2,3. Those in high-risk occupations had to adapt using recommended crisis capacity strategies and the public adopted the use of non-specialized items such as cloth material face coverings primarily for source control, but also to provide some respiratory protection for wearers. In the United States, specialized respiratory protection (i.e., filtering facepiece respirators (FFRs) such as N95s) was reserved for some of these high-risk occupations (e.g., healthcare) during supply shortages4. When little was known about severe acute respiratory syndrome coronavirus 2 (SARS-Cov-2) transmission, a variety of other types of clothing materials were also considered as barrier protection early in the pandemic5. With the diversity of fabrics being used for wearer protection, questions arose about the use, reuse, and disinfection/decontamination of these items. While in the United States it was generally accepted that routine home machine laundering of face coverings and other clothing items rendered viruses on those surfaces non-infectious, little data existed to validate this claim, and there was a lack of published laboratory protocols for testing. The purpose of the research protocol presented here is to provide an example of a laboratory process for conducting laundering studies that generate data on viral disinfection. While the protocol was developed for research during the COVID-19 pandemic, it is intended to be a framework adaptable to other virus disinfection studies.
The role of clothing in disease transmission is a difficult concept to quantify. The International Scientific Forum on Home Hygiene attempted this challenging task by conducting a review of the role of clothing in the spread of infectious disease coupled with a risk assessment of home hygiene practices6. Included in this work was the review of several scientific studies that examined the survival of different viral strains on different types of fabrics such as wool and cotton7,8,9,10,11. Each study focused on a different type of virus including vaccinia, poliovirus, respiratory syncytial virus, herpesvirus, and influenza virus. The survival times of the different viruses on the fabrics ranged from 30 min to 5 months depending on the virus-material combination. Several of the studies also demonstrated the transfer of viral contamination from the material onto hands. As part of the publication, effective laundering was discussed as an important management technique to reduce transmission but recognized that the magnitude of the impact of laundering on reducing disease burden was dependent on the specific viral contaminant and difficult to quantify7,8,9,10,11.
The laundering process destroys microorganisms using chemical, physical, and thermal treatment processes. For example, soaps and detergents can separate soils and may impart some chemically mediated antimicrobial action. Physically, dilution and agitation may aid in the reduction in viral loads. A study examining the persistence of human coronavirus HCoV-OC43 on cotton swatches using industrial and domestic wash cycles with and without temperature and detergent found no detectable virus when washing in unheated water without detergent, but that in the presence of a soil load (artificial saliva), domestic wash cycles required detergent for samples to have non-detect virus loadings12. Hot water itself can also provide an effective means of destroying some microorganisms13,14.
In a recent publication summarizing the state of current laundry practices, many factors such as fabric composition, storage conditions, dirt load, wash temperature and time, and drying temperature was identified as varying in global practices of laundering15. While laundering is a common cleaning method for a large percentage of the population, this large variation in existing practices makes issuing detailed guidance for how to do this safely and effectively, when an item may be contaminated by a virus, challenging and sparse. During the COVID-19 pandemic, the United States Centers for Disease Control and Prevention (CDC) issued guidance on how to launder items for homeowners16,17. Much of this laundering guidance was based on several older studies on bacterial disinfection18,19 and supported by several benchtop studies that have found enveloped viruses inactivated in water with detergents20,21. The guidance can be summarized as 1) follow the manufacturer's instructions for the detergent, 2) use the warmest appropriate water setting, and 3) dry items completely. The rationale of these recommendations was that washing on the warmest possible cycle with detergent combined with drying completely (with heat if possible) will kill the SARS-CoV-2 virus.
The sheer number of possible variations in the laundering process necessitates a uniform protocol, such as presented here, to be able to isolate variables and test the viral disinfection efficacy of specific processes. The intent of this protocol coupled with an instructional video is to demonstrate a laboratory-based hot water laundering process for replication in other research studies. Additionally, the results of this viral disinfection efficacy testing should build consumer confidence in the effectiveness of home laundering during viral-based pandemics.
Phi6 was received from a collaborator laboratory as a ~1 mL frozen aliquot and was stored at -80 °C until use. It was initially used to propagate more virus stocks which were subsequently stored at -80 °C until use. Phi6 was selected as the demonstration virus because it is commonly used as a model enveloped virus, can be propagated to high titers, and requires a low biosafety level laboratory to perform the testing22,23,24.
1. Prepare virus stock solution
2. Perform pre-test visual assessment of PPE item
Figure 1. PPE pre-test assessment measurement locations. Denim, scrub, and face-covering locations where the length was recorded for tracking material changes from the laundering process. Please click here to view a larger version of this figure.
3. Prepare coupons
4. Perform inoculation
Figure 2. Test coupon locations on denim, scrubs, and face coverings. Letters A-D corresponds to the unique coupon identifiers for all laundering experiments. Please click here to view a larger version of this figure.
5. Perform laundering
6. Extract and enumerate viral loads on coupons
7. Perform post-test visual assessment of PPE item(s)
Several different types of quality control data and results are generated after completion of this protocol. Plaque forming unit (PFU) plate counts along with the extracted sample volume enable the calculation of the number of PFU per test coupon. Table 2 is an example of a data recording sheet for serial dilution/plating results. Using the dilution factor, sample volume, and plate count from Table 1, Table 3 shows representative viral recovery results for a face covering test. Note that these data include the test coupons and the quality control samples for the inoculum, coupons, and wash water (with and without detergent). The procedural blank and sterility quality control samples are important for confirming that the water solutions and PPE materials were not contaminated with Phi6. Indication of contamination would cause erroneous calculations of disinfection efficacy and require the test to be repeated. The positive control samples are intended to verify that the virus stock solution did not environmentally/naturally degrade during the experiments, thereby inflating the effect of the laundering process in viral load reduction. These samples should remain within 1 log PFU of the inoculum controls to accept the test coupon results. A large reduction in PFU of the positive control samples also indicates that all steps of the coupon inoculation should be carefully reviewed to ensure that the analyst is executing the protocol with proper pipetting and spreading techniques.
This protocol also provides information for assessing changes to the material properties of clothing items due to laundering and quality control information pertaining to the protocol (Table 4 and Figure 3). These data are useful for several reasons. Recording the trends in measurements of the PPE items allows for the identification of an item with a manufacturing defect. This identification may help to explain outlier microbial data and contextualize the variation in product behavior. Taking notes of odors or damage may also provide an indication if the washer or dryer was operating sub-optimally during an experiment and if the tests should be repeated or the equipment serviced. Additionally, if the test plan calls for multiple laundering cycles of the same PPE item, the data may help determine how long the PPE items maintain their integrity for use when laundering. Keeping a record of the pH of the detergent solution provides an alert to changes in the water source or the detergent product. Maintaining a time log of the laundering steps ensures that the timer on the washer and dryer does not cause variations to the experimental protocol.
Ultimately, these data are used to report the disinfection efficacy of the hot water laundering procedure against a surrogate for viral pathogens. Laundering disinfection efficacy (Eqn. 1) is calculated by subtraction of the average log10 virus recoveries from PPE test coupon from the average log10 virus recoveries from PPE positive control results (Figure 4). For test coupon results that are non-detect, the log10 of the detection limit is used in the disinfection efficacy calculation. It is common to report disinfection efficacy as log values for comparison with other viral disinfection techniques and standards.
Disinfection Efficacy = Average log10 (Positive Controls) - Average log10 (Test Coupons) (Eqn. 1)
Figure 3. Change in PPE dimensions by location. Δ = Pre-test measurement - post-test measurement. A negative Δ value corresponds to the stretching of the item at the specified location and a positive value corresponds to shrinkage. Please click here to view a larger version of this figure.
Figure 4. Efficacy of hot water laundering at disinfecting face coverings, denim, and scrub PPE materials from Phi6. Stars denote full disinfection occurred (non-detects on the test coupons). Error bars indicate standard deviation (n = 3). Location letters correspond to the placement depicted in Figure 2. Please click here to view a larger version of this figure.
Table 1. Solution recipes. Ingredients and amounts necessary to prepare tryptic soy agar, tryptic soy broth, and beef extract solutions. Please click here to download this Table.
Table 2. An example portion of a serial dilution/plating results sheet. Template for reporting raw microbial data. Please click here to download this Table.
Table 3. Face covering microbial results. Example summary sheet for processed plaque-forming unit (PFU) data. Please click here to download this Table.
Table 4. Scrubs quality control and material assessment log. Template for reporting calibration of pH probe, pH of detergent solution, pre-and post-wash measurements, and laundering cycle times. Please click here to download this Table.
This protocol was developed to execute systematic laboratory testing to assess the laundering effectiveness of viral disinfection from full-sized PPE/clothing items. The procedures outline the critical steps for preparing the virus, inoculating the test material, assessing the changes to the items due to the laundering process, and quantifying the reduction in viral load as a result of the laundering (machine washing and drying) process. Additionally, the protocol outlines the necessary quality control samples for ensuring the experiments are not biased by contamination and measurements/observations that should be recorded to track the material integrity of the PPE items after multiple laundering cycles. The results using Phi6 indicate that the hot water laundering process used in this protocol achieved a greater than 3-log reduction in viral load for all samples (face covering, scrubs, and denim pants). The viral load reduction was also uniform across different locations on the PPE/clothing items. To demonstrate 3-log reduction, this protocol requires the use of a high viral load and a stabilizing agent (beef extract) that may not be representative of the soil load for all situations.
Mini washers and compact dryers were selected to optimize the number of replicate experiments that could be conducted in a space-constrained setting and to keep the sterilization of equipment and water volume used during the experiments manageable for laboratory staff. As a result of using the mini washer, the rinsing steps were manual as compared to most home laundering applications that are fully automated. It is also important to remember that machine washing predominates in developed countries, but handwashing is still practiced all over the world15. Additionally, some may not have access to hot water for washing, and others manually air-dry clothes rather than machine drying. These differences in laundering practices were not addressed in this current protocol but could easily be investigated with minor modifications such as substituting the washing and drying steps with using a bucket and a close line
There has been minimal focus on the cleaning/disinfecting of virally contaminated face coverings and street clothing in the scientific literature at the full scale. More commonly, studies assess the filtration performance of face coverings after repeated washing and drying but do not evaluate viral disinfection efficacy27,28. For example, Clapp et al. evaluated fitted filtration efficiency of cloth masks and modified procedure masks and found wide variation in performance, with simple modifications providing increased fit and filtration efficiency29. Another study looked at the filtration efficiency of four cloth masks of different materials30, again focusing on source control or personal protection. This may be due to a lack of specialization for both the microbial portion and mechanical testing in the same laboratory. The protocol presented here provides an evaluation of disinfection efficacy as well as material degradation.
There have been a number of decontamination/disinfection methods for disposable respiratory protection (primarily N95s) recently published in the scientific literature31,32,33. The primary focus on FFRs (e.g., N95s) is due to the critical respiratory protection they provide for healthcare workers and other front-line occupations. Primary technologies for respirator decontamination involved vaporized hydrogen peroxide (VHP), ultraviolet germicidal radiation (UVGI), and moist heat (steam) for virus inactivation. Viscusi et al. evaluated five decontamination methods for FFRs and UVGI; ethylene oxide and VHP were found to be the most promising decontamination methods31. Fischer et al. evaluated four different decontamination methods-UV light, dry heat, 70% ethanol, and VHP-for their ability to reduce contamination with SARS-CoV-2 and their effect on N95 respirator function32. There are many additional studies on effective decontamination technologies for FFRs which were summarized and published in 202033. However, these specialized methods aren't accessible or designed to be used safely by the average home or small business owner.
This protocol was developed using Phi6, an enveloped bacteriophage that is similar to SARS-CoV-2, has spike proteins, and is of similar size (80-100 nm)34, for all testing. Since Phi6 is not a known pathogen, it can be manipulated in a general microbiological Biosafety Level 1 (BSL-1) laboratory. Efficacy against Phi6 may indicate the efficacy of other enveloped viruses, however, empirical verification for each virus of interest is necessary35. By using a similar, nonpathogenic viral agent, it is hoped that this protocol can be repeated elsewhere and used for studying future viral epidemics/pandemics. Future research may include the use of disinfectants (e.g., bleach) in addition to detergents and a standardized protocol for hand washing and line drying.
The U.S. Environmental Protection Agency (EPA) through its Office of Research and Development directed the research described herein under EP-C-15-008 with Jacobs Technology Inc. It has been reviewed by the Agency but does not necessarily reflect the Agency's views. No official endorsement should be inferred. EPA does not endorse the purchase or sale of any commercial products or services. The authors would like to thank EPA contractors Denise Aslett for the oversight of the EPA RTP microbiology, Brian Ford, Rachael Baartmans, and Lesley Mendez Sandoval for their work on this project in the EPA RTP microbiology lab, Ramona Sherman for providing the EPA quality assurance review, and Worth Calfee and Shannon Serre for providing EPA technical reviews.
Name | Company | Catalog Number | Comments |
 Freezer (- 80 °C) | ThermoFisher Scientific | FDE30086FA | |
 Hot Plate | VWR | 97042-714 | |
 Safety Pins (steel) | Singer | 319921 | |
 Shaker | Lab-Line Instruments, Inc. | 3525 | |
 SM buffer | Teknova, Hollister, CA | S0249 | |
 Syringe filter (0.2 μm) | Corning, Corning, NY | PES syringe filters, 431229 | |
1X Phosphate Buffered Saline | Teknova, Hollister, CA | P0196, 10X PBS solution | |
Agar | Becton Dickinson | 214010 | |
Autoclavable caps | DWK Life Sciences, Millville, NJ | KIM-KAP Caps, 73663-18 | |
Autoclave | Steris | AMSCO 250LS Steam Sterilizer Model 20VS | |
Beef Extract | Sigma-Aldrich, Millipore Sigma, St. Louis, MO, USA | P/N B4888-100g | |
Calcium chloride | Sigma-Aldrich | 793639 | |
Cell spreaders | Busse Hospital Disposables | 23600894 | |
Centrifuge | ThermoFisher Scientific | 75004271 | Heraeus MegaFuge 16R Centrifuge |
Certified Timer | https://nist.time.gov/ | Not Applicable | |
Conical tubes (50 mL) | Corning Life Sciences | 352098 | Falcon 50-mL high-clarity polypropylene conical centrifuge tubes |
Cryovials | Thermo Fisher Scientific, Waltham, MA | AY509X33 | |
Denim | Wrangler | Rustler Regular Fit Straight Leg Jean Four Pocket Jean with Scoop Front Pockets, PN:87619PW | |
Detergent | Proctor and Gamble | Tide Original Scent Liquid Laundry Detergent Product Number (PN): 003700023068 | |
Dextrose | Fisher | BP350 | |
Dey-Engley neutralizing broth | Becton Dickinson | DF0819172 | |
Dryer | Magic Chef | MCSDRY15W | |
Face Coverings | Felina | Reusable Organic Cotton Face Masks, PN: 990121P4 | |
Incubator (top agar) | Symphony | 414004-596 | |
Laboratory Notebook | Scientific Notebook Company | 2001 | |
Magnesium chloride | Sigma-Aldrich | M9272 | |
Media sterilization and dispensing system | Integra | Media Clave/Media Jet | |
Petri Dishes (100 mm) | VWR | 25384-342 | |
pH Meter | Orion/Oakton | STARA1110/EW-35634-35 | |
pH Probe | Orion | 8157BNUMD | |
pH Standards | Oakton | 00654-(00/04/08) | |
Phi 6 and Pseudomonas syringae | Battelle Memorial Institute, Columbus, OH | Not Applicable | |
Pipette & Tips | Rainin | (Pipettes) 17014391, 17002921; (Pipette Tips) 30389239, 17014382 | |
Refrigerator | True Manufacturing Co., Inc. | GDM-33 | |
Scrubs | Gogreen cool | PN: WS19100PT | |
Sodium chloride | Sigma-Aldrich | 57656 | |
Stir Bar | Fisherbrand | 16-800-512 | |
Tape Measure | Lufkin | PS3425 | |
Test Tubes for Soft agar (14 mL) | Corning, Corning, NY | 352059 | |
Thermometer | Fisherbrand | 14-983-19B | |
Tryptone | Sigma-Aldrich | T9410 | |
Vaporous hydrogen peroxide sterilization bags | STERIS | 62020TW | |
Vortex (during the plating process) | Daigger Scientific, Inc | 3030A | Vortex Genie 2 |
Vortex (for sample extraction) | Branson Ultrasonics | 58816-115 | Multi-Tube vortexer |
Washer | Kuppet | KP1040600A | |
Washer Sterilization | Steris | STERIS VHP ED1000 generator | |
Yeast extract | Gibco | 212750 |
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