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Scientific Reports volume 13, Article number: 12983 (2023)
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The World Health Organization’s R&D Blueprint list of priority diseases for 2022 includes Lassa fever, signifying the need for research and development in emergency contexts. This disease is caused by the arenavirus Lassa virus (LASV). Being an enveloped virus, LASV should be susceptible to a variety of microbicidal actives, although empirical data to support this expectation are needed. We evaluated the virucidal efficacy of sodium hypochlorite, ethanol, a formulated dual quaternary ammonium compound, an accelerated hydrogen peroxide formulation, and a p-chloro-m-xylenol formulation, per ASTM E1052-20, against LASV engineered to express green fluorescent protein (GFP). A 10-μL volume of virus in tripartite soil (bovine serum albumin, tryptone, and mucin) was combined with 50 μL of disinfectant in suspension for 0.5, 1, 5, or 10 min at 20–25 °C. Neutralized test mixtures were quantified by GFP expression to determine log10 reduction. Remaining material was passaged on Vero cells to confirm absence of residual infectious virus. Input virus titers of 6.6–8.0 log10 per assay were completely inactivated by each disinfectant within 1–5 min contact time. The rapid and substantial inactivation of LASV suggests the utility of these microbicides for mitigating spread of infectious virus during Lassa fever outbreaks.
The World Health Organization (WHO)’s R&D Blueprint list of priority diseases1 comprises a list of diseases for which “… given their potential to cause a public health emergency and the absence of efficacious drugs and/or vaccines, there is an urgent need for accelerated research and development…”1. One of the listed diseases is Lassa fever, which is caused by Lassa virus (LASV), an enveloped virus from the Arenaviridae family (genus Mammarenavirus). This rapidly expanding RNA virus family has been established for a number of genetically related viruses, including several that, like LASV, frequently cause lethal zoonoses. These include Chapare virus, Lujo virus, Machupo virus, Junín virus, Guanarito virus, and Sabiá virus2.
One of the concerning knowledge gaps for the diseases highlighted in the WHO R&D Blueprint list of priority diseases, including Lassa fever, is the lack of empirical data for the effectiveness of virucides against the infectious agents that might be used for applications, including air sanitization, skin sanitization, liquid inactivation, and inanimate surface hygiene3. The few manuscripts that have been published on the inactivation of LASV by microbicides (acetic acid, formalin, β-propiolactone, and phenol/guanidine thiocyanate) addressed only the efficacy in rendering laboratory specimens safe for handling within diagnostic and histology laboratories. In addition, review of this literature3 has indicated that the secondary literature sources for efficacy of more commonly used surface-hygiene microbicides for inactivating arenaviruses, including LASV, have not supported efficacy claims with primary literature citations.
Resolving this particular knowledge gap for LASV and many of the other viruses causing priority list diseases has been limited, in part, due to the need for manipulating such viruses within maximum containment (termed in Northern America biosafety level 4 [BSL-4]) laboratories. In the present study, we were able to leverage the BSL-4 laboratory at Public Health Agency of Canada, Winnipeg, MB, Canada, and a LASV engineered4 to express green fluorescent protein (GFP). Using standardized methodologies described in ASTM E-1052-205, we have evaluated the virucidal efficacy of commonly used microbicidal actives (sodium hypochlorite and ethanol), and formulations containing a dual quaternary ammonium compound (QAC), accelerated hydrogen peroxide (AHP), and p-chloro-m-xylenol (PCMX) against LASV in suspension in the presence of a tripartite soil load6. Organic soil loads are used as the challenge matrix to model virus inactivation by microbicides in relevant matrices, such as human sputum or blood. Use of hard water as diluent for specific actives was included in the study design, because it is a known antagonist to microbicidal activity and is commonly available in the field7.
In addition to the methodologies in ASTM E-1052-20, our study was made more stringent by decreasing the volume of the microbicides used during testing and by ruling out the presence of residual infectious LASV in the post-disinfection/post-neutralization samples through use of a safety test (performed in addition to the standard quantification of titer reduction). This safety test involved inoculation of 650 µL of undiluted neutralized test sample onto six-well plates containing Chlorocebus aethiops kidney epithelial (Vero) cells and passaging any cultures found to be negative for GFP at least twice. This was done to evaluate the virucidal efficacy test for the possibility of any residual virus being present at levels lower than the limit of detection of the 50% tissue culture infectious dose (TCID50) titration assay performed in Vero cells per the ASTM standard.
Grivet (Chlorocebus aethiops) kidney epithelial (Vero) cells (American Type Culture Collection [ATCC], Manassas, VA, USA; #CCL-81) were maintained at 37 °C with 5% carbon dioxide (CO2) in minimum essential medium (MEM; HyClone, Logan, UT, USA) supplemented with 5% heat-inactivated fetal calf serum (FCS; Gibco, Grand Island, NY, USA) and 10 units per mL penicillin/streptomycin (pen/strep; Gibco). Lassa virus (Josiah strain) expressing green fluorescent protein (LASV-GFP) was amplified and used, as previously described4, for all assays. All culture manipulations involving LASV-GFP were performed in a BSL-4 laboratory at the Canadian Science Centre for Human and Animal Health, Winnipeg, MB, Canada.
A characterized stock of LASV-GFP was prepared by exposing ten T75 flasks of Vero cells at ≈80% confluency at a multiplicity of infection of 0.01 viral particles per cell. At 4 d post-infection, essentially all cells within the confluent cell monolayers were observed to express GFP. The flasks were then placed in a freezer at − 70 °C. The frozen flasks were thawed on the following day and the conditioned media was removed and clarified by low-speed centrifugation (4500 × g) for 10 min. The resulting supernatants were pooled and layered onto 20% w/v sucrose cushions prepared in Tris-NaCl-EDTA buffer prepared in house. The pooled supernatants were subjected to centrifugation (≈130,000 × g for 2 h), and the viral pellets obtained were resuspended in MEM containing 2% FCS and 10 units per mL pen/strep to create virus culture medium (VCM). The virus pool obtained was aliquoted into small portions that were frozen at − 70 °C. The stock virus titer was found to be > 9.2 log10 per mL, as determined by TCID50 assay, using the method described by Reed and Muench8.
A variety of microbicidal actives or formulations containing microbicidal actives were evaluated for virucidal efficacy against LASV-GFP. The microbicides tested are listed in Table 1, along with sources and the supplied and tested concentrations.
Neutralizing reagents or mechanical removal using Amicon filter columns were evaluated for ability to neutralize the virucidal effects of the microbicides to enable investigation of specific contact times, and/or to mitigate the cytotoxic effects of the microbicides on the Vero cells used to assay residual virus. The procedures used are described in Supplemental Materials.
The LASV-GFP suspension inactivation efficacy testing of the microbicides (Fig. 1) was conducted at ambient temperature using ASTM E-1052-205. A modification to the standard method was made to reduce the volume of test microbicide, increasing the stringency of the evaluation. Stocks of LASV-GFP in tripartite soil load6 were prepared on the day of assay. Briefly, a single tube of stock virus was removed from frozen storage and mixed with a tripartite soil load (≈1.7 × 109 TCID50 per mL virus, 0.25% bovine serum albumin, 0.35% tryptone, 0.08% mucin). The virus/tripartite soil load mixture (10 µL) was added to 50 µL of prepared microbicide or to 50 µL of VCM to create the positive virus control. A similar preparation was used to challenge the efficacy of the test microbicides. The virus/tripartite soil mixture was incubated with the test microbicide at room temperature for contact times of 30 s, 1 min, 5 min, and 10 min. At the end of each time point, the microbicides were neutralized, either by adding 940 µL of VCM (Fig. 1) or by adding 500 μL VCM and filtering out the microbicides using a YM100 Amicon column (Fig. 2). All studies involving LASV-GFP were conducted within a BSL-4 facility.
Schematic representation of the suspension inactivation efficacy testing methodology performed using neutralization by VCM (minimal essential medium + 2% fetal calf serum + 10 units per mL penicillin/streptomycin) alone. The entire procedure was performed three times for each microbicide evaluated, in three technical replicates each, as depicted.
Schematic representation of the suspension inactivation efficacy testing methodology using VCM (minimal essential medium + 2% fetal calf serum + 10 units per mL penicillin/streptomycin) and mechanical neutralization using Amicon Spin Columns. The entire procedure was performed three times for each microbicide evaluated, in three technical replicates each, as depicted.
For microbicides that could not be adequately neutralized using VCM alone (AHP, PCMX, and dual QAC), a mechanical filtration procedure via Amicon YM100 columns (UFCS510096; EMD Millipore, Darmstadt, Germany) was used during virucidal efficacy testing (Fig. 2). After the planned contact times, virus-microbicide suspensions were diluted with 500 μL of VCM and immediately eluted through the columns. In accordance with the manufacturer’s procedures, the columns were centrifuged for 3 min at 14,000 × g and the flow-through was discarded. To the retentate, 400 μL of fresh VCM were then added to the filter cup, centrifuged for an additional 3 min at 14,000 × g, and the flow-through was again discarded. To elute retained virus from the column, 500 μL of fresh VCM were added to the filter cup, incubated for 2 min, inverted into a fresh tube, and spun for 2 min at 1000 × g. The final eluted volumes were brought to 1000 μL with VCM for evaluation. A single wash step was performed for the AHP and PCMX, whereas four wash steps were needed for the dual QAC.
In either case (neutralization using VCM alone or VCM plus neutralization using Amicon columns), a 350-µL portion of neutralized test solution was assayed for residual infectious virus titer using a ten-fold dilution scheme in VCM, with 50 µL of each resulting dilution being added to 96-well plates of Vero cells (n = 5 replicate wells per dilution). The inoculated cell monolayers were scored 5 d post-infection for GFP, and virus titers (in units of TCID50) were calculated according to the Reed-Muench method8.
In addition to the 96-well plate TCID50 assay described above, neutralized material also was evaluated for low levels of infectious virus in a plate safety test. In this test, which is used when dealing with especially lethal challenge viruses, 650 μL of remaining undiluted neutralized test sample (one sample for each technical replicate) were added to Vero cells in wells of a six-well plate containing 4 mL of VCM. In addition, an inoculum containing < 5 TCID50 units of LASV-GFP was used in each six-well plate to serve as a positive control. All wells were scored 5 d post-infection for presence or absence of the fluorescence associated with GFP (indicative of LASV-GFP-infected cells). The confirmed ability of this assay to detect very low concentrations (< 5 TCID50 units) of the positive control virus indicates its sensitivity and provides confidence that a negative result in the separate TCID50 assay truly reflects the absence of residual infectious LASV-GFP in the neutralized test samples.
For each disinfectant, three separate independent assays were conducted with each time point having three technical replicates within each assay. TCID50 titers for positive virus controls and neutralized microbicide test conditions were determined using the method of Reed and Muench8. The log10 reduction values achieved by the microbicides at given contact times were calculated by subtracting the post-disinfection log10 TCID50 values (titers) from the log10 TCID50 values obtained for the corresponding positive virus control. Statistical comparison of the mean (n = 5 replicates) viral titers obtained in the neutralization effectiveness studies (Supplemental Fig. S1) was performed using a non-parametric unpaired t-test, with statistical significance set at p < 0.05.
The results from the determination of the effectiveness of the neutralization procedures (chemical or mechanical) are provided in the Supplemental Materials. It was found that 0.5% sodium hypochlorite and 67% ethanol could be adequately neutralized using VCM alone. VCM plus mechanical neutralization using Amicon columns was required for dual QAC, AHP, and PCMX.
Three replicate evaluations of the efficacy of 0.5% (5000 ppm) sodium hypochlorite (NaOCl) (Table 1) for inactivating LASV-GFP virus in suspension were conducted. Contact times of 0.5, 1, 5, and 10 min were evaluated at ambient temperature. A mean LASV-GFP titer of 6.66 log10 TCID50 per mL (4.6 × 106 TCID50 per mL) was recovered for the positive control (no disinfectant) (Fig. 3). The post-exposure/neutralization titer for the 0.5% sodium hypochlorite condition was 0.42 log10 TCID50 per mL after a 0.5-min (30-s) contact time, representing a 6.2 log10 reduction. After 1, 5, and 10 min of contact with 0.5% sodium hypochlorite, complete inactivation (≥ 6.7 log10) of LASV-GFP was observed (Fig. 3).
Efficacy of 0.5% sodium hypochlorite for inactivating Lassa virus in suspension. Error bars indicate standard deviation of the mean for n = 3 independent studies with 3 technical replicates each.
Further evidence of the complete inactivation of LASV-GFP following the 1-, 5-, and 10-min contact times was obtained in the plate safety test (Table 2). In this assay (depicted schematically in Fig. 2), undiluted post-exposure/neutralization mixture (650 μL per technical replicate onto one well per replicate) was added to six-well plates of Vero cells, which were passaged up to two times to determine residual infectious virus. One technical replicate from one assay of the 0.5-min contact time displayed GFP in this assay. No evidence of residual infectious virus was obtained from the technical replicates for the 1-, 5-, and 10-min contact times (Table 2).
Three replicate evaluations of the efficacy of 67% ethanol (EtOH) (Table 1) for inactivating LASV-GFP virus in suspension were conducted. Contact times of 0.5, 1, 5, and 10 min were evaluated at ambient temperature. A mean LASV-GFP titer of 6.62 log10 TCID50 per mL (4.4 × 106 TCID50 per mL) was recovered for the positive control (no disinfectant) (Fig. 4). The post-exposure/neutralization titers for the 67% ethanol condition were 0.42 log10 TCID50 per mL for the 0.5-min (30-s) contact time and 0.42 log10 TCID50 per mL for the 1-min contact time. These correspond to reductions of 6.2 log10. After 5 and 10 min of contact with 67% ethanol, complete inactivation (≥ 6.6 log10) of LASV-GFP was observed (Fig. 4).
Efficacy of 67% ethanol for inactivating Lassa virus in suspension. Error bars indicate standard deviation of the mean for n = 3 independent studies with 3 technical replicates each.
Further evidence of the complete inactivation of LASV-GFP following the 5- and 10-min contact times was obtained in the plate safety test. One technical replicate from one assay of the 0.5 min contact time and three technical replicates from two assays of the 1-min contact time displayed GFP in this assay. No evidence of residual infectious virus was obtained from the technical replicates for the 5- and 10-min contact times (Table 3).
Three replicate evaluations of the efficacy of a dual QAC formulation (Table 1) for inactivating LASV-GFP virus in suspension were conducted. Contact times of 0.5, 1, 5, and 10 min were evaluated at ambient temperature. A mean LASV-GFP titer of 8 log10 TCID50 per mL was recovered for the positive control (no disinfectant) (Fig. 5). The post-exposure/neutralization titers for the dual QAC conditions were ≤ 1.8 log10 TCID50 per mL (the defined limit of detection of the titration assay) for all contact times (Fig. 5). The assay limit of detection was determined by residual cytotoxicity to the Vero cells of the neutralization mixture following elution from the Amicon column. These results indicate a reduction in titer of LASV of ≤ 6.2 log10 for each contact time.
Efficacy of a 2% dual quaternary ammonium compound (QAC) formulation for inactivating Lassa virus in suspension. The limit of detection of the titration assay (1.8 × 101 TCID50 per mL) is indicated by the solid blue horizontal line. Error bars indicate standard deviation of the mean for n = 3 independent studies with 3 technical replicates each.
In the case of the dual QAC formulation, the plate safety test was not able to be conducted, due to the residual cytotoxicity of the undiluted post-exposure/neutralization samples to the Vero cells despite repeated mitigation efforts using multiple filtrations via Amicon columns.
Three replicate evaluations of the efficacy of an AHP formulation (Table 1) for inactivating LASV-GFP virus in suspension were conducted. Contact times of 0.5, 1, 5, and 10 min were evaluated at ambient temperature. A mean LASV-GFP titer of 7.3 log10 TCID50 per mL was recovered for the positive control (no disinfectant) (Fig. 6). The post-exposure/neutralization titer for the AHP condition was 0.17 log10 TCID50 per mL for the 0.5-min (30-s) contact time, representing a 7.1 log10 reduction. After 1, 5, and 10 min of contact with AHP, complete inactivation (≥ 7.3 log10) of LASV-GFP was observed (Fig. 6).
Efficacy of an accelerated hydrogen peroxide formulation (AHP; 1:40 dilution) for inactivating Lassa virus in suspension. Error bars indicate standard deviation of the mean for n = 3 independent studies with 3 technical replicates each.
Further evidence of the complete inactivation of LASV-GFP following the 1-, 5-, and 10-min contact times for AHP was obtained in the plate safety test. Two technical replicates from one assay of the 0.5-min (30-s) contact time displayed GFP in this assay. No evidence of residual infectious virus was obtained from the technical replicates for the 1-, 5-, 10-min contact times (Table 4).
Three replicate evaluations of the efficacy of three in-test concentrations (0.04, 0.06, and 0.12%) of PCMX in a commercial formulation (Table 1) for inactivating LASV-GFP virus in suspension were conducted. Contact times of 0.5, 1, 5, and 10 min were evaluated at ambient temperature. Mean LASV-GFP titers of 7.8 log10 TCID50 per mL, 7.3 log10 TCID50 per mL, and 7.3 log10 TCID50 per mL were recovered for the positive control (no disinfectant) conditions for the assay of the 0.12, 0.06, and 0.04% in-test concentrations of PCMX, respectively (Fig. 7).
Efficacy of p-chloro-m-xylenol (PCMX) at test concentrations of 0.04, 0.06, and 0.12% for inactivating Lassa virus in suspension. Error bars indicate standard deviation of the mean for n = 3 independent studies with 3 technical replicates each.
PCMX concentration-dependent inactivation of LASV-GFP was observed at the various contact times. For instance, the post-exposure/neutralization titers for the 0.12, 0.06, and 0.04% PCMX conditions were 0.9 log10 TCID50 per mL, 2.3 log10 TCID50 per mL, and 3.2 log10 TCID50 per mL, respectively, after 0.5-min (30-s) contact time, representing log10 reductions of 6.9, 5.0, and 4.1 log10, respectively. Following a 1-min contact time, the 0.12% PCMX condition had no viable virus remaining post-exposure/neutralization, whereas for the 0.06 and 0.04% PCMX conditions 1.0 and 2.4 log10 TCID50 per mL, respectively, were recovered representing log10 reductions of 6.3 and 4.9 log10, respectively. Following a 5-min contact time, the post-exposure/neutralization titers for the 0.06 and 0.04% PCMX conditions were 0.97 and 0.94 log10 TCID50 per mL, respectively, representing log10 reductions of 6.3 and 6.4 log10, respectively. Complete inactivation (≥ 7.8 log10) of LASV-GFP was afforded by 0.12% PCMX at contact times of 1, 5, and 10 min. For the 0.06 and 0.04% PCMX concentrations, complete inactivation (≥ 7.3 log10) of LASV-GFP was observed at the 10-min contact time (Fig. 7).
Further evidence of the complete inactivation of LASV-GFP following the 1-, 5-, and 10-min contact times for 0.12% PCMX, and following the 10-min contact times for 0.06 and 0.04% PCMX, was obtained in the plate safety tests (Tables 5, 6, 7). One technical replicate from one assay of the 0.5-min contact time displayed GFP in the plate safety test for 0.12% PCMX, whereas no evidence of residual infectious virus was obtained from the technical replicates for the 1-, 5-, and 10-min contact times (Table 5).
As expected on the basis of the titration assay results, multiple replicates for one or more individual assays for the 0.06 and 0.04% PCMX concentrations demonstrated GFP following the 0.5-, 1-, and 5-min contact times, confirming the presence of residual infectious virus in these replicates. No evidence of residual infectious virus was obtained from the technical replicates for the 10-min contact times for the 0.06 and 0.04% PCMX exposures (Tables 6 and 7).
Per WHO9, Lassa fever is endemic in a number of Western African countries, including Benin, Ghana, Guinea, Liberia, Mali, Sierra Leone, and Nigeria. Cases have been reported as recently as March 2023 in Ghana9. Natal mastomys rats (murid Mastomys natalensis) are the primary reservoirs of the causal virus, LASV. Transmission to humans occurs primarily through contact with urine or feces of infected mastomys, but human-to-human transmission via direct contact with blood or bodily fluids may also occur, especially in hospital settings9. These considerations suggest that inanimate surface hygiene and liquid inactivation methods for LASV might limit dissemination of the virus to humans.
Partly because maximum containment is needed for conduct of inactivation studies on LASV, there is little published information on the efficacy of microbicides for inactivation of this arenavirus. A recent review of the available primary data on efficacy of microbicides against LASV3 revealed that the limited published data pertained to the inactivation of laboratory specimens intended for diagnostic or histology applications10,11,12,13,14. The paucity of virucidal data of microbicides against LASV is also emphasized in a recent review of inactivation of emerging viruses in aqueous phase15. Our study was intended to resolve this knowledge gap, supplying efficacy information for commonly used microbicidal actives and formulations applicable to inactivation of LASV in liquid suspension.
The United States Environmental Protection Agency (US EPA) recognizes that microbicidal efficacy data may not be available for newly emerging viruses, especially those requiring BSL-4 laboratories for handling the viruses safely. The EPA, therefore, enacted a policy in 2016 enabling efficacy claims against emerging viruses to be made without having provided registration data specifically for those viruses. In its Guidance to Registrants16, the EPA has made note of the hierarchy of pathogen susceptibility to microbicides17,18,19,20,21 in recognizing that efficacy against one enveloped virus implies efficacy against other enveloped viruses. The EPA policy provides a “process that can be used to identify effective disinfectant products for use against emerging viral pathogens and to permit registrants to make limited claims of their product’s efficacy against such pathogens.”16. The guidance outlines “a voluntary two stage process, involving product label amendments and modified terms of registration and applies only to emerging viruses”16.
The EPA policy provides inanimate surface hygiene and liquid inactivation alternatives, helpful for use during virus disease outbreaks. Despite this, obtaining empirical data for specific emerging viruses is required for assurance of efficacy against the more lethal viruses. On the basis of information3 derived from testing enveloped viruses (such as, Ebola virus and SARS-CoV-2), lipid-disrupting agents—including ethanol, quaternary ammonium compounds (such as the dual QAC compound evaluated), and phenolics (such as PCMX)—were expected to be effective against other enveloped viruses, such as LASV. Certain microbicidal actives and formulations were considered mechanistically to be protein-denaturing agents (ethanol, PCMX, AHP, and sodium hypochlorite) or genome-degrading agents (ethanol, AHP, and sodium hypochlorite). In fact, our study found that these agents caused rapid (i.e., within 30 s contact time) and highly effective (≥ 6 log10) inactivation of LASV-GFP when tested in suspension in a tripartite soil load with hard water as diluent to simulate field use of dilutable products, including PCMX and sodium hypochlorite (Table 1).
The standardized ASTM E-1052-20 methodology5 is based on demonstrating a reduction in infectious virus titer after exposure to a test microbicide. These data are then available for making EPA disinfectant efficacy claims. For instance, the EPA stated the following in its 2012 disinfectant product guidance22 that “The product should demonstrate complete inactivation of the virus at all dilutions. If cytotoxicity is present, the virus control titer should be increased to demonstrate a ≥ 3 log10 reduction in viral titer beyond the cytotoxic level.” For disinfectants that are non-cytotoxic to the cellular infectivity assays used for demonstrating efficacy, a 4-log10 reduction in viral titer is typically considered to be effective. However, as we have previously done when dealing with especially lethal viruses, such as Ebola virus23,24, we extended the stringency of the assay for detecting residual infectious virus post-exposure to the microbicides by conducting the plate safety test. The latter enabled any infectious virus remaining post-exposure/neutralization to amplify in Vero cells in a six-well plate format, with up to two passages onto fresh cells performed for negative wells. This additional test was used to confirm that conditions scored negative in the TCID50 titration assay were, in fact, free of infectious virus.
In a recently published preprint25, Shaffer et al. have reported on the persistence of LASV Josiah and Sauerwald isolates on hard surfaces and in water. Approximately 1.9 log10 reduction in titer per day was observed on high-density polyethylene (HDPE) and stainless steel surfaces for the Josiah isolate, and approximately 1.2 log10 per day on these surfaces for the Sauerwald isolate. These data indicate that surface contamination with infectious LASV could persist for days, depending on the initial titer of the deposited virus. Decay rates for the two isolates in deionized water (0.1 to 0.15 log10 per day) and wastewater (0.6 to 0.8 log10 per day) were observed25. Inactivation of the two LASV isolates by sodium hypochlorite (1, 5, or 10 mg/L [ppm]) was concentration dependent, with the Sauerwald isolate displaying greater susceptibility to inactivation, with no reasons for this difference being offered in the paper25. Greater than 4 log10 inactivation of LASV occurred within 5 min contact time with 1 to 10 mg/L [ppm] sodium hypochlorite for each isolate25. These sodium hypochlorite concentrations are quite low, compared to the concentration used in our study (0.5% [5000 ppm]), and to concentrations proposed previously for use against LASV (0.5–1%)26.
In conclusion, we have provided empirical evidence of the virucidal efficacy of commonly employed microbicidal actives (ethanol and sodium hypochlorite) and formulations of microbicidal actives (AHP, PCMX, and dual QAC) for LASV. Each of these, at the appropriate concentration and contact time, was capable of reducing the titer of infectious virus by > 6 log10, even in the presence of a tripartite organic load7,27. In future studies, we plan to explore the more stringent virucidal efficacy of a similar set of microbicidal actives and formulations against LASV in carrier-inactivation studies of the virus dried on a hard surface and performed in accordance with ASTM-E2197-117.
Supplementary information accompanies this paper at https://doi.org/10.1038/s41598-023-38954-5. Additional datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
World Health Organization. R&D Blueprint list of priority diseases. (2018). http://www.who.int/blueprint/priority-diseases/en/.
Radoshitzky, S. R. et al. ICTV virus taxonomy profile: Arenaviridae. J Gen Virol 100(8), 1200–1201. https://doi.org/10.1099/jgv.0.001280 (2019).
Article  CAS  PubMed  Google Scholar 
Ijaz, M. K., Nims, R. W., Cutts, T. A., McKinney, J. & Gerba, C. P. Predicted and measured virucidal efficacies of microbicides for emerging and reemerging viruses associated with WHO priority diseases. In Disinfection of Viruses (eds Nims, R. W. & Khalid Ijaz, M.) (Intech Open, London, 2022).
Google Scholar 
Caì, Y. et al. Recombinant Lassa virus expressing green fluorescent protein as a tool for high-throughput drug screens and neutralizing antibody assays. Viruses 10(11), 655. https://doi.org/10.3390/v10110655 (2018).
Article  CAS  PubMed  PubMed Central  Google Scholar 
ASTM International. ASTM E1052-20. Standard Test Method to Assess the Activity of Microbicides against Viruses in Suspension. (2020). https://webstore.ansi.org/standards/astm/astme105220?gclid=EAIaIQobChMI7q797q3__AIVcS2tBh3glwi7EAAYAiAAEgLaaPD_BwE.
ASTM International. ASTM E1052-11. Standard Test Method to Assess the Activity of Microbicides against Viruses in Suspension (2011). https://webstore.ansi.org/standards/astm/astme105211?gclid=EAIaIQobChMIkMDEza___AIVYxqtBh3NXgtpEAAYAiAAEgIGr_D_BwE.
ASTM International. ASTM E2197-11. Standard Quantitative Disk Carrier Test Method for Determining the Bactericidal, Virucidal, Fungicidal, Mycobactericidal and Sporicidal Activities of Liquid Chemical Germicides (2011). https://webstore.ansi.org/standards/astm/astme219711.
Reed, L. J. & Muench, H. A simple method of estimating fifty percent endpoints. Am. J. Hyg. 27, 493–497 (1938).
Google Scholar 
ProMED. International Society for Infectious Diseases. Lassa Fever – West Africa – Ghana. (2023) http://outbreaknewstoday.com/ghana-reports-12-additional-lassa-fever-cases-63186/.
Olschewski, S. et al. Validation of inactivation methods for arenaviruses. Viruses 13, 968. https://doi.org/10.3390/v13060968 (2021).
Article  CAS  PubMed  PubMed Central  Google Scholar 
Lloyd, G., Bowen, E. T. W. & Slade, J. H. R. Physical and chemical methods of inactivating Lassa virus. Lancet 319(8280), P1046-1048 (1982).
Article  Google Scholar 
Mitchell, S. W. & McCormick, J. B. Physicochemical inactivation of Lassa, Ebola, and Marburg viruses and effect on clinical laboratory analysis. J. Clin. Microbiol. 20(3), 486–489 (1984).
Article  CAS  PubMed  PubMed Central  Google Scholar 
Kochel, T. J., Kocher, G. A., Ksiazek, T. G. & Burans, J. P. Evaluation of TRIzol LS inactivation of viruses. ABSA Int. 22(2), 52–55 (2017).
Google Scholar 
Retterer, C. et al. Strategies for validation of inactivation of viruses with Trizol® LS and formalin solutions. ABSA Int. 25(2), 74–82 (2020).
Google Scholar 
Hossain, F. Sources, enumerations, and inactivation mechanisms of four emerging viruses in aqueous phase. J. Water Health 20(2), 396. https://doi.org/10.2166/wh.2022.263 (2022).
Article  PubMed  Google Scholar 
US Environmental Protection Agency. Guidance to registrants: Process for making claims against emerging viral pathogens not on EPA-registered disinfectant labels. (2016). https://www.epa.gov/sites/production/files/2016-09/documents/emerging_viral_pathogen_program_guidance_final_8_19_16_001_0.pdf.
Spaulding, E. H. Chemical disinfection of medical and surgical materials. In Disinfection, Sterilization, & Preservation 3rd edn (ed. Block, S.) (Lea & Febiger, 1968).
Google Scholar 
Klein, M. & Deforest, A. Principles of viral inactivation. In Disinfection, Sterilization, & Preservation 3rd edn (ed. Block, S.) (Lea & Febiger, 1968).
Google Scholar 
Sattar, S. A. Hierarchy of susceptibility of viruses to environmental surface disinfectants: A predictor of activity against new and emerging viral pathogens. J AOAC Int. 90(6), 1655–1658 (2007).
Article  CAS  PubMed  Google Scholar 
Ijaz, M. K. & Rubino, J. R. Should test methods for disinfectants use vertebrate virus dried on carriers to advance virucidal claims?. Infect. Control Hosp. Epidemiol. 29(2), 192–194 (2008).
Article  PubMed  Google Scholar 
Ijaz, M. K., Sattar, S. A., Rubino, J. R., Nims, R. W. & Gerba, C. P. Combating SARS-CoV-2: Leveraging microbicidal experiences with other emerging/re-emerging viruses. PeerJ 8, e9914. https://doi.org/10.7717/peerj.9914 (2020).
Article  PubMed  PubMed Central  Google Scholar 
US Environmental Protection Agency. Product Performance Test Guidelines OCSPP 810.2200: Disinfectants for Use on Hard Surfaces – Efficacy Data Recommendations. (2012). https://www.regulations.gov/document?D=EPA-HQ-OPPT-2009-0150-0021.
Cutts, T. A., Ijaz, M. K., Nims, R. W., Rubino, J. R. & Theriault, S. S. Effectiveness of dettol antiseptic liquid for inactivation of Ebola virus in suspension. Sci. Rep. 9, 6590. https://doi.org/10.1038/s41598-019-42386-5 (2019).
Article  ADS  CAS  PubMed  PubMed Central  Google Scholar 
Cutts, T. A. et al. Efficacy of microbicides for inactivation of Ebola-Makona virus on a non-porous surface – A targeted hygiene intervention for reducing virus spread. Sci. Rep. 10, 15247. https://doi.org/10.1038/s41598-020-71736-x (2020).
Article  ADS  CAS  PubMed  PubMed Central  Google Scholar 
Shaffer, M. et al. Environmental persistence and disinfection of Lassa virus. bioRxiv https://doi.org/10.1101/2023.05.17.541161 (2023).
Article  PubMed  PubMed Central  Google Scholar 
Killoran, K. E., Larson, K. L. Lassa virus. Iowa State University. 2016; https://www.swinehealth.org/wp-content/uploads/2016/08/Lassa_Virus.pdf.
Sattar, S. A., Springthorpe, V. S., Adegbunrin, O., Zafer, A. A. & Busa, M. A disc-based quantitative carrier test method to assess the virucidal activity of chemical germicides. J. Virol. Meth. 112(1–2), 3–12 (2003).
Article  CAS  Google Scholar 
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The authors thank Kelly Anderson of Public Health Agency of Canada and Mark Ripley and Chris Jones of Reckitt Benckiser LLC for critical review of the manuscript and approval for publication. The authors thank Anya Crane (National Institutes of Health [NIH] National Institute of Allergy and Infectious Diseases [NIAID] Division of Clinical Research [DCR] Integrated Research Facility at Fort Detrick [IRF-Frederick]) for critically editing the manuscript.
The Public Health Agency of Canada, Applied Biosafety Research Program, provided partial funding and test products for the project. The following statement applies specifically to the engineering of the LASV to express GFP. No NIH funding was received for the microbicide efficacy studies described in this paper. This work was supported in part through the Laulima Government Solutions, LLC, prime contract with the National Institutes of Health (NIH) National Institute of Allergy and Infectious Diseases (NIAID), under Contract No. HHSN272201800013C. J.H.K. performed this work as an employee of Tunnell Government Services (TGS), a subcontractor of Laulima Government Solutions, LLC, under Contract No. HHSN272201800013C. The views and conclusions contained in this document are those of the authors and should not be interpreted as necessarily representing the official policies, either expressed or implied, of the U.S. Department of Health and Human Services or of the institutions and companies affiliated with the authors, nor does mention of trade names, commercial products, or organizations imply endorsement by the U.S. Government.
Applied Biosafety Research Program, Public Health Agency of Canada, 1015 Arlington St., Winnipeg, MB, R3E 3P6, Canada
Todd A. Cutts
Syner-G Biopharma, 6000 Spine Road, Suite 201, Boulder, CO, 80301, USA
Raymond W. Nims
Global Research and Development for Lysol and Dettol, Reckitt Benckiser LLC, One Philips Parkway, Montvale, NJ, 07645, USA
Joseph R. Rubino, Julie McKinney & M. Khalid Ijaz
Integrated Research Facility at Fort Detrick, National Institute of Allergy and Infectious Diseases, National Institutes of Health, B-8200 Research Plaza, Fort Detrick, Frederick, MD, 21702, USA
Jens H. Kuhn
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T.A.C., J.R.R., and M.K.I. designed and approved the project and experimental design; T.A.C. performed the experiments in the BSL-4 facility and aided in assembling the experimental data; T.A.C., R.W.N., J.R.R., J.M., J.H.K., and M.K.I. contributed to data analysis and interpretation, preparation of the figures, and to authorship of the manuscript.
Correspondence to M. Khalid Ijaz.
R.W. Nims received a fee from Reckitt Benckiser for authoring and editing the manuscript. The other authors declare no competing interests.
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Cutts, T.A., Nims, R.W., Rubino, J.R. et al. Efficacy of microbicidal actives and formulations for inactivation of Lassa virus in suspension. Sci Rep 13, 12983 (2023). https://doi.org/10.1038/s41598-023-38954-5
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DOI: https://doi.org/10.1038/s41598-023-38954-5
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