key: cord-1006419-hbovh7s9 authors: Alsved, Malin; Widell, Anders; Dahlin, Henrik; Karlson, Sara; Medstrand, Patrik; Löndahl, Jakob title: Aerosolization and recovery of viable murine norovirus in an experimental setup date: 2020-09-29 journal: Sci Rep DOI: 10.1038/s41598-020-72932-5 sha: bcddaa6fa2883f92f5b3ddf29ba2d974d66963fd doc_id: 1006419 cord_uid: hbovh7s9 Noroviruses are the major cause for viral acute gastroenteritis in the world. Despite the existing infection prevention strategies in hospitals, the disease continues to spread and causes extensive and numerous outbreaks. Hence, there is a need to investigate the possibility of airborne transmission of norovirus. In this study, we developed an experimental setup for studies on the infectivity of aerosolized murine norovirus (MNV), a model for the human norovirus. Two aerosol generation principles were evaluated: bubble bursting, a common natural aerosolization mechanism, and nebulization, a common aerosolization technique in laboratory studies. The aerosolization setup was characterized by physical and viral dilution factors, generated aerosol particle size distributions, and the viral infectivity after aerosolization. We found a lower physical dilution factor when using the nebulization generator than with the bubble bursting generator. The viral dilution factor of the system was higher than the physical dilution; however, when comparing the physical and viral dilution factors, bubble bursting generation was more efficient. The infectivity per virus was similar using either generation principle, suggesting that the generation itself had a minor impact on MNV infectivity and that instead, the effect of drying in air could be a major reason for infectivity losses. The hypothesis that the human norovirus (NoV) to some extent can be spread through air is gaining more support as recent studies detected NoV RNA in air during outbreaks in hospitals 1 , close to symptomatic patients 2 , and after simulated floor cleaning procedures 3 . Possible sources of airborne NoV in real-life settings are bubble bursting during vomiting and toilet flushing 2, 4 or resuspension from contaminated surfaces 3 . Our recent findings showing that aerosol particles smaller than 1 µm in diameter contain detectable amounts of NoV RNA indicate that viruses can travel longer distances than splashing droplets (2 m) and also remain airborne for longer periods of time 2 . Today, there are only scarce estimates of the importance of airborne NoV contribution to the overall transmission of the disease 5 . A key knowledge gap concerns the ability of viruses to preserve their infectivity in air under different conditions. Improved knowledge of this issue is necessary to establish effective measures for disease control. In order to address this issue, information on parameters that influence infectivity of airborne noroviruses is crucial. However, the infectivity of airborne human noroviruses has not been possible to assess in real-world environments, nor in laboratory experiments, since there is no well-established cell culturing system for these viruses working at the low concentrations obtained in air samples 6 . To be able to study NoV viability, the cultivable murine norovirus (MNV) is frequently used as a model 7, 8 . Moreover, MNV infections are a common problem in mice in laboratory animal facilities 9 . Evaluations of viral infectivity after aerosolization have been performed in previous studies 1, [10] [11] [12] [13] [14] [15] [16] [17] . Yet, many of these studies lack a detailed representation of the generated aerosol, such as size characterization from nanometer to micrometer sized aerosol particles, physical dilution factor (or spray factor) of the setup, and the effect of drying on particle size 18 . The aerosol particle size is important since it influences the residence time in air, the amount of protective material surrounding the viruses, and in some cases also the severity of the infection in the host 19 . Several studies report detection of viruses in airborne sub-micrometer particles 2, [20] [21] [22] . These smaller aerosol particles may be of special importance in disease transmission as they may remain airborne for long periods of time (hours) and easily deposit in the respiratory tract during inhalation. Thus, there is a need for more research targeting such small aerosol particles. We developed an experimental setup for aerosolization and collection of MNV with subsequent infectivity assessment in cell cultures (Fig. 1) . MNV was aerosolized through either bubble bursting (by the SLAG) or twin fluid nebulization (by the atomizer). The generated liquid aerosol droplets were dried to droplet nuclei particles in the air, similar to aerosol droplets formed in real-world settings in air at regular relative humidity (RH < 70%). The MNV containing aerosol was collected in a liquid impinger and analyzed for infectivity by inoculation of permissive cell cultures. Detection of intracellular nsRNA by strand specific quantitative reverse transcription (qRT) PCR in these cell cultures was used as a measure of virus infectivity since the nsRNA is specific for replication. The viral dilution factor was determined by qRT-PCR targeting the MNV genome -the positive sense RNA (psRNA) -in the starting liquid and the collection liquid. The physical dilution factor of the aerosolization setup was evaluated using a radioactive tracer ( 99m Technetium). Black arrows represent the aerosol flow, and the circled 'P's indicates where pressurized air was connected to the aerosol generators. The aerosol was dried in a diffusion dryer before entering the flow tube, where it was diluted with particle-free air. At the end of the flow tube, the aerosol particle concentration was monitored with a scanning mobility particle sizer (SMPS) and an aerodynamic particle sizer (APS), and collected into a BioSampler impinger for analysis. All ports for excess air at the end of the flow tube were connected to HEPA filters. The aerosol generation mechanisms for the SLAG and the atomizer are outlined in b). The collection liquid in the BioSampler was analyzed by a viral infectivity assay and by viral RNA quantification, outlined in c). SLAG: Sparging liquid aerosol generator; HEPA filter: high efficiency particulate air filter; nsRNA: negative sense RNA; psRNA: positive sense RNA; MNV: murine norovirus; qRT-PCR: quantitative reverse transcriptase polymerase chain reaction. physical and viral dilution factors of the system. The radioactive nuclei 99m Tc was used as a tracer molecule in the aerosolized solution to allow for high-resolution determination of the dilution factor from starting liquid to collection liquid in the setup. The collection of aerosol generated by the SLAG resulted in a physical dilution factor of 2.4 log 10 , three times higher than the dilution factor for the atomizer, which was 1.9 log 10 (mean of triplicate runs). Aerosolization of 99m Tc was also used to evaluate the collection efficiency of the BioSampler for the generated aerosols by comparison with collection on filters. Relative to the particle filters, the BioSampler collected 66% and 84% of the particle volume generated by the SLAG and the atomizer, respectively. The lower collection efficiency of the SLAG aerosol can be explained by the larger amount of particle mass below 0.5 µm (Fig. 2b ) that is not efficiently collected by the BioSampler 11 . This difference in particle size can also explain the higher physical dilution factor observed for the SLAG aerosol than for the atomizer aerosol. The viral dilution factor was determined as the psMNV concentrations in the start solution compared to the collection solution. For both aerosol generators, the viral dilution factors were higher than the physical. However, the difference was threefold for the SLAG aerosol while eightfold for the atomizer aerosol. Taken together, as compared to the atomizer, a smaller amount of SLAG aerosol is collected by the BioSampler (i.e., higher physical dilution), but these particles contain more MNV psRNA copies (lower viral dilution relative the physical dilution). Negative sense RNA detection in infected RAW 264.7 cells. Detection of nsRNA by qRT-PCR in cell homogenates was performed with a limit of detection of 50 RNA copies per reaction (Cycle threshold; Ct ~ 40). Both the positive and negative strand specific qRT-PCR assays were run with their respective opposite sense RNA standards to determine the concentrations needed to avoid false priming amplification. Using the The corresponding Ct-value for falsely detected nsRNA using the positive sense primers was 33 for an nsRNA concentration of 5 × 10 6 copies. As noted by Vashist et al. 33 , unspecific priming could occur from the RT enzyme itself, which showed up in our analysis as a secondary melting temperature in the melting curve in samples with low template RNA. Thus, samples without the correct melting temperature were discarded and a cut-off at Ct 40 was used. optimization of incubation time for negative sense RnA detection. Optimal incubation time for nsRNA detection inside the infected cells was evaluated by a time series analysis of the nsRNA concentrations. The nsRNA concentration increased with longer incubation time up to 24 h (Fig. 3a) . A maximum nsRNA was reached at 12 h for the wells inoculated with the highest viral load due to rapid cell death (verified by microscopy). The cells inoculated with the lowest viral concentration (10 5 dilution factor) displayed nsRNA quantities close to or below the limit of detection after 8 and 12 h incubation. Therefore, the incubation times 16 h and 72 h were evaluated in a second time series experiment (Fig. 3b) . However, 16 h also resulted in undetectable nsRNA values with the 10 5 diluted inocula and 72 h resulted in decreased nsRNA concentrations for all dilutions compared to 24 h. Thus, 24 h was chosen as the optimal incubation time for the low infectivity aerosol samples. Regression lines were fitted to the same data as in Fig. 3a , for evaluation of the relation between nsRNA quantities and the viral inoculation concentration after the different incubation times (Fig. 4) . Here, the samples that had already reached maximum nsRNA quantities (10 0 after 12 h, and 10 0 and 10 1 after 24 h) due to cell death were excluded from the fit. Significant correlations between nsRNA quantity and viral inoculation concentration infectivity of aerosolized murine norovirus. Virus infectivity after aerosolization and collection were evaluated by cell inoculations with serially diluted aerosol samples. Each inoculated cell culture was assessed qualitatively for infectivity by detection of intracellular nsRNA, and was then used to calculate the 50% tissue culture infectious dose (TCID 50 ) mL −1 (Fig. 5 ). The TCID 50 mL −1 values were similar for the MNV from both generators, which agrees well because the genome concentrations (psRNA) were also analogous. The 2.8 log 10 viral dilution factor, together with the viral infectivity loss, resulted in a 5 log 10 factor reduction in TCID 50 mL −1 . The viral infectivity loss per viral genome copy was, hence, reduced a factor of ~ 2 log 10 for both aerosol generators. Understanding the mechanisms by which viral diseases can be transmitted through air is of importance for the development of accurate infection prevention guidelines and practices. Noroviruses, which traditionally have not been considered to transmit via air, have nevertheless been detected in air samples 1, 2, 34 . This gives reason to study the ability of noroviruses to maintain infectivity after aerosolization. In this study, we developed a methodology for studying infectivity of aerosolized MNV, a model virus for human norovirus. We observed that viable virus could be transferred but that the infectivity levels were reduced by two orders of magnitude after airborne transport. The aerosolization setup developed in this study has similarities with previously described systems 1, 11, 12, 25, [35] [36] [37] [38] , however our characterization of the setup is extensive and contributes detailed information on system performance. We also evaluated two aerosol generators for usage in aerosolization studies on viruses, since their aerosolization mechanisms are physically different: the SLAG simulates natural bubble bursting, while the Collison type atomizer utilizes twin-fluid nebulization frequently used in laboratory studies. In addition, we used a radioactive tracer to obtain the physical dilution factor with higher precision than with common chemical tracers, and an alternative method for validation of infected cell cultures using negative strand specific qRT-PCR. Previous studies have focused either on the physical dilution factor 39, 40 or the viral genome dilution factor (together with infectivity reduction) 12, 14, 15 . Here we compared these two, and found that the physical dilution factors for both aerosol generators were lower than the viral dilution factors (Fig. 5) . Both MNV and radioactive tracer were mixed in the same starting solution and thus, the observed disparity could be due to an uneven distribution of MNV in the droplets. As the atomizer is based on shear forces, supposedly both the radioactive molecule and the virus should be evenly distributed in the liquid, and hence, also in the generated aerosol droplets, as has been shown by Pan et al. 15 . Another reason could be due to losses of MNV that stick to the BioSampler glass container surfaces, while 99m Tc molecules to a higher degree remain dissolved in the sampling liquid. Compared to the atomizer, the SLAG aerosol was collected less efficiently by the BioSampler due to the generation of fewer large particles (Fig. 2a) . This was also demonstrated by a larger physical dilution of the radioactive tracer (Fig. 5) . Nevertheless, the viral dilution factors for both generators were similar. Thus, the bubble bursting aerosolization appears to be more efficient than the atomizer in generating virus-containing particles that are collected. Presumably, a higher concentration of MNV in larger droplets could result in this. The physics and fluid mechanics behind bubble bursting in non-clean water have recently been investigated by Poulain and Bourouiba 41 , showing that surfactants released from microorganisms may enhance aerosol droplet formation www.nature.com/scientificreports/ upon bubble bursting. If the same mechanisms can explain enhanced virus aerosolization from bubble bursting remains to be explored. The SLAG has only been used for aerosolization of influenza virus in one previous study 36 , but then no infectious virus was detected in the collected samples. This may be due to a lower emission rate of the SLAG compared to most atomizers. In our study, the atomizer generated approximately the same amount of aerosol at an airflow rate of 2 L min −1 as the SLAG at 10 L min −1 . The MNV (about 30 nm in diameter) is at least one order of magnitude smaller than the generated aerosol droplets and do seemingly not influence the droplet size distribution 11, 15 . The majority of the droplets generated here were smaller than 1 µm. We have shown in a previous study that human norovirus can be present in sub-micrometer particles in hospital wards during outbreaks 2 . Hence, there is a need to also include also these smaller particles in studies on viral aerosolization. Considering that the majority of bioaerosol particles in the environment are 1-10 µm in diameter 42 , most aerosol samplers have their highest collection efficiencies in that size range. However, viruses have been found in sub-micrometer particles both in the environment and in laboratory studies 2, 20, 22, 36, 43, 44 , thus, a higher collection efficiency for small particles would greatly improve studies on aerosolized viruses. A recently developed technology for bioaerosol collection based on condensational growth has been shown to have > 95% collection efficiency for sub-micrometer aerosol particles, which would give a more representable result as viruses in all particle sizes are included in the downstream analysis 15 . The condensational growth collector has a liquid collection volume that is ten times smaller than that of the BioSampler, which would increase the virus concentration in the collected sample. This up-concentration would be advantageous for further studies on virus infectivity using the setup, because the infectivity detection assay presented here was close to the detection limit. The decreased MNV infectivity after aerosolization in this setup was reduced almost to the same amount (comparing infectivity/genome copy number) by the SLAG and the atomizer, which suggests that for this MNV, the aerosolization mechanism had little impact on infectivity. The atomizer recirculated the liquid, which is known to degrade biological cell membranes 25 and cause water to evaporate 37 . Previous studies also did not find any loss of viability in MNV after 25 min recirculation in a Single-Jet atomizer 1 , and in coronavirus after recirculation in a Collison nebulizer 37 , even though coronaviruses are enveloped viruses. Instead, it has been shown that drying can be detrimental for non-enveloped viruses 10 . Moreover, viruses aerosolized from liquids with low-solute concentrations showed reduced infectivity 10 . These two parameters, drying and low-solute solution, could explain the difference in MNV infectivity observed here and in the previous study by Bonifait et al. 1 . Bonifait et al. used an aerosol generator that produced droplets around 1.5 µm in diameter, which is about 7 times larger in diameter (> 100 times larger volume) than the droplets produced in this study. They also aerosolized MNV in virus growth medium, while in our study, MNV in growth media was diluted 1:10 in PBS (due to foaming in the SLAG). Drying of MNV in laboratory settings has also been performed on surfaces 45, 46 . These studies found that MNV dried in larger droplets (100-200 µL) or at higher relative humidity was more likely to be inactivated, and it was hypothesized that the drying time, rather than the fact that water was removed, was the likely reason for MNV inactivation 45 . These results taken together, suggest that MNV is likely to remain infectious if dried fast (however, not completely) in a solution with protective molecules (proteins and sugars). Samples collected from aerosols often exhibit low viral concentrations 12 and therefore require a method with high sensitivity for infectivity detection. A previous study developed a method for molecular detection of an infection-specific molecule for MNV: the negative strand RNA (nsRNA), which is the complementary strand to the viral genome 33 . The nsRNA is produced inside cells exclusively during ongoing replication, thereby serving as a qualitative marker for infection. This method can result in fewer false negatives than the conventional observation of the cytopathic effect (CPE) in cell cultures, since the sensitivity of qRT-PCR is high. Other advantages are that the molecular analysis is objective, and that it does not require personnel with long experience of cell work. However, using nsRNA detection as a qualitative determiner still requires inoculation with serial dilutions to obtain a quantitative value of infectivity, such as the TCID 50 . The risk for false priming of the opposite sense RNA in the qPCR step was investigated by adding psRNA to the nsRNA assay (primers for nsRNA), and vice versa. Since we needed to add a high psRNA concentration of 5 × 10 6 copies per reaction to reach a borderline positivity (Ct value of 40), the specificity of the key nsRNA assay is sufficiently high. In addition, Vashist et al. showed that including both negative and positive sense RNA in the RT step for cDNA synthesis did not alter the qPCR results for either set of primers. Unspecific priming of the RT enzyme occurred only when there was no amount or too low amounts of RNA template and could be identified by lower melt temperatures; hence, samples with aberrant melting temperatures were not included in the analysis. Santiana et al. showed that MNV replication occur mainly within 24 h of incubation, while 90% of the cells were still intact 31 . Most of the cell membrane damages took place after 24 h and during this period MNV replication was limited. This pattern is in agreement with our results that show the highest nsRNA concentrations around 24 h, and then decreasing amounts due to cell death (Fig. 3 ). In addition, the time series analysis can be used for estimates of the infectivity of samples by simply harvesting cells at 24 h, purify and amplify nsRNA and plot the nsRNA Ct values against a standard curve. This would simplify comparisons in future studies of incremental changes in aerosol parameters (humidity, temperature, etc.). To observe a CPE in cell cultures, an incubation time of 72 h was needed. However, after 72 h, many cells were destroyed and the intracellular nsRNA was degraded. As the infectivity was strongly reduced after aerosolization, the nsRNA detection after 24 h was chosen instead of CPE observation after 72 h. The experimental setup described here highlights some difficulties in studies on aerosolized viruses: (1) the lack of standards in how to generate bioaerosol that results in significant differences in aerosol particle size and concentration, (2) the necessity to determine both physical and viral dilution factors, and (3) www.nature.com/scientificreports/ during airborne transport due to the low-solute solution and dilution in the setup. By thorough characterization and description of the system performance and the aerosol characteristics, we provide new information on submicrometer aerosol particle generation and the effects on MNV infectivity. In addition, our results suggest that virus aerosolization by bubble bursting may be advantageous. The aerosolization setup developed in this study allows for further analysis of how the infectivity of airborne MNV is affected by factors in the environment, such as temperature, relative humidity and aerosol particle size. This may lead to a deeper understanding of seasonal and regional differences in virus transmission and offer better tools to minimize the spread of viral aerosols, and thus, prevent spreading of diseases. Methods experimental aerosolization setup. An experimental setup for aerosolization and collection of viruses was developed (Fig. 1) , where either a Collison type atomizer (Constant Output Atomizer, model 3076, TSI Inc.) or a SLAG (Sparging Liquid Aerosol Generator, CH Technologies) was used as the aerosol generator. The atomizer generated droplets by using a high perpendicular airflow to break up a thin liquid column (see schematic in Fig. 1, lower left panel) . The largest droplets impacted on the wall inside the generator and were recirculated. In the SLAG, the solution to be aerosolized was dropped onto a porous stainless steel plate at a flow rate of 0.5 mL min −1 delivered by a syringe pump. At the same time, air was blown through the porous plate from below, bubbling through the liquid film of the MNV suspension, generating droplets though bubble bursting (see schematic in Fig. 1, lower left panel) . The atomizer was operated at 1.2 bar and a 2 L min −1 output airflow rate, and the SLAG at a 10 L min −1 output flow rate. The generated aerosols were dried in a silica diffusion dryer (DDU 570, Topas GmbH) and then mixed with a perpendicular dilution flow in a stainless steel flow tube to a total airflow rate of 18 L min −1 . At this flow rate the particles were airborne about 10 s before collection at the end of the flow tube. Aerosol particles were collected by a BioSampler impinger (SKC Inc.), with 20 mL PBS as collection liquid, at an airflow rate of 12.5 L min −1 . Aerosol particle size characterization. The Characterization of the initial droplet sizes of the generated aerosol was performed using a 1% ammonium sulphate solution, which was chosen because it forms spherical particles when dried 47 . Using the measured dry salt aerosol particles d dry , the originally generated droplet diameters d wet were calculated with Eqs. 1 and 2: where m wet is the mass of the wet droplet, m dry is the mass of the dry particle, f salt is the mass fraction of salt in the solution, and ρ dry and ρ wet are the densities for dry particles and wet droplets. The wet droplet diameters range was 0.060-80 µm, with a gap between 3.4 and 5.0 µm where the instrumental measurements did not overlap. physical dilution factor by radioactive tracer. The physical dilution factor of the aerosolization setup was determined by aerosolization of radioactive 99m Tc in a solution of PBS and 10% growth media containing MNV (same solution properties as those used for MNV aerosolization). Three runs of 30 min aerosolization were performed with each aerosol generator and triplicate (1 mL) aliquots were used for the analysis. The same start solution was used for both generators. Gamma-ray spectroscopy was used to measure the radioactivity from 99m Tc by means of a sodium iodine well count detector (1480 Wizard, Perkin Elmer). The gamma radiation emitted from the start solution was then compared to that of the collection liquid. In addition, PBS was analyzed as a reference. The measuring time for each sample was set to 90 s, and the results were adjusted for radioactive decay during the measurement time. The instrument automatically corrected for background activity. All samples were below the max count rate of 2 million counts per minute, where the dead time error is < 1%. The collection efficiencies of the BioSampler for the two generated aerosols were evaluated by parallel collection of radioactive aerosol particles on a 25 mm HA filter with 0.45 µm pore size (Millipore). The filter sampled close to 100% of all particles at a flow rate of 1 L min −1 (data not shown). Filters were placed in sample tubes (same as for liquid samples) with a pincer and analyzed together with the liquid samples by gamma-ray spectroscopy. For comparison, the radioactivity from the BioSampler and the filter were normalized by their respective sampling airflow. Aerosolization of murine noroviruses. The MNV stock solution in growth media was diluted 1:10 in PBS to decrease foaming due to high viscosity (primarily problematic in the SLAG) before aerosolization. The start solution was inserted into the atomizer flask or the syringe connected to the SLAG, and aerosolization with collection into the BioSampler was run for 30 min. Aerosolization was performed in triplicates for each aerosol generator. Samples were taken from the start solution before the experiment and from the collection liquid in the BioSampler after the experiment. Samples were stored in − 80 °C freezer until analysis was performed, either by the MNV infectivity assay or by qRT-PCR for quantification (viral dilution factor). Cells were grown in 6 mL media at 37 °C and 5% CO 2 . The cell culture was split three times per week by gently scraping cells off the flask bottom, and transferring 1/5 of the cells to fresh growth media in a new flask. The cell concentration before every split was determined by Trypan blue staining (1:1) and cell counting (EVE Automated Cell Counter, Nanoentek). infectivity analysis of MnV. Prior to viral inoculations in 24-well plates, 800,000 freshly split cells were added per well (in 400 µL media) and allowed to grow overnight to a monolayer. After the incubation, the supernatant from each well was removed and the cells were washed with PBS. Viral tenfold dilution series in PBS were prepared and 400 µL were added to each well and incubated for 1 h, and were then replaced by fresh growth medium and incubated for the assigned incubation time (24 h for aerosol samples). After incubation, the supernatant was removed and the cells were washed with PBS, and thereafter lysed with 350 µL RLT lysis buffer (RNeasy Mini Kit, Qiagen, Inc.) and all samples were stored at − 20 °C. Intracellular RNA was extracted from the samples using the RNeasy Mini Kit (Qiagen, Inc.) and then treated with DNase (Thermo Fisher Scientific) for 30 min at 37 °C, according to the protocol of the manufacturer. Extracted RNA samples were stored at − 80 °C. Strand specific quantitative reverse transcription PCR. During replication of the genomic psRNA, MNV produces an intermediate stage of nsRNA that is used for generating multiple copies of psRNA. The number of nsRNA copies is usually orders of magnitudes lower than the number of psRNA copies. Hence, detection of the nsRNA, unique for viral replication, calls for a specific reverse transcription step starting from a primer that is uniquely hybridizing to the negative strand. For MNV, such a strand-specific method has been described by Vashist et al. 33 and shown to be specific. We have used this methodology here (as well as in previous studies 46 ). In short, the transcription primer targeting the nsRNA has an added non-viral oligonucleotide sequence in its 5′-end. In the subsequent qPCR reaction, a primer identical to the non-viral oligonucleotide tag is used in order to only amplify what was transcribed using the tagged primers. A similar reverse tagged transcription step was used to target the more abundant psRNA. Both negative and positive strand transcriptions were conducted with SuperScript IV in a thermal cycler (Applied Biosystems 2720) according to previously developed methodology 33, 46 . These samples containing cDNA transcripts were stored at − 20 °C until quantification by qPCR. SYBR Select Master Mix (Thermo Fisher Scientific) was used for qPCR in 20 µL reactions using a StepOnePlus Real-Time PCR system (Applied Biosystems). For relative quantification, serially diluted positive sense and negative sense cDNA respectively, with a concentration of 2.5 × 10 6 copies µL −1 were included in the qPCR setup. The data was analyzed in StepOne Software v 2.3. Determining the tciD 50 of the aerosolized samples. Detection of nsRNA by qRT-PCR was used as a qualitative measure of infection in each well sample and used to calculate the TCID 50 mL −1 48 . The TCID 50 was determined per aerosolization run (three per aerosol generator) based on triplicate wells per dilution, and the mean and standard deviation of these were used for comparisons. The TCID 50 mL −1 was correspondingly determined for the start solution. time series analysis of intracellular negative sense RnA. To find the optimal incubation time for viral samples with low concentrations (i.e., the collected aerosol samples) a time series analysis was performed to evaluate the nsRNA concentration at various incubation times. The MNV stock solution was diluted in growth media in tenfold dilution series, ranging from zero to 10 10 times dilution. Three 24-well plates were inoculated with viral solution (duplicate wells) as described above. After the inoculation, the plates were incubated with fresh media for 8, 12 and 24 h, respectively. After the assigned incubation time, the supernatant was removed and the cells were lysed as above. The plates were stored at − 20 °C until RNA extraction and further analysis by qRT-PCR for detection and quantification of nsRNA, as described above. A second time series analysis experiment was performed with the incubation times 12, 16, 24 and 72 h. Statistics. Aerosolization and collection were performed in triplicate runs for each aerosol generator, and the mean and standard deviation for each set of triplicate runs were calculated. The dilution factors were calculated by dividing the mean value of the start liquid concentration by the mean value of the collection liquid concentration. Triplicate aliquots were extracted from the collection liquids for the 99m Tc analysis, as well as for the psRNA quantification, and the means of those were used to represent one sample. The qPCR analysis was performed using duplicate reactions and the mean of those was used. Linear regression analysis using the ANOVA test on the log-transformed data was used to compare the quantities of nsRNA with inoculation dilutions in Fig. 4 . Detection and quantification of airborne norovirus during outbreaks in healthcare facilities Sources of airborne norovirus in hospital outbreaks Norovirus recovery from floors and air after various decontamination protocols Aerosol generation by modern flush toilets Routes of transmission of influenza A H1N1, SARS CoV, and norovirus in air cabin: comparative analyses Replication of human noroviruses in stem cell-derived human enteroids Surrogates for the study of norovirus stability and inactivation in the environment: a comparison of murine norovirus and feline calicivirus Detection of murine norovirus 1 by using plaque assay, transfection assay, and real-time reverse transcription-PCR before and after heat exposure Murine norovirus detection in the exhaust air of IVCs is more sensitive than serological analysis of soiled bedding sentinels Some factors affecting the survival of airborne viruses Sampling methodologies and dosage assessment techniques for submicrometre and ultrafine virus aerosol particles Comparison of five bacteriophages as models for viral aerosol studies Airborne micro-organisms: survival tests with four viruses Resistance of aerosolized bacterial viruses to relative humidity and temperature Determination of the distribution of infectious viruses in aerosol particles using water-based condensational growth technology and a bacteriophage MS2 model A vibrating mesh nebulizer as an alternative to the Collison 3-jet nebulizer for infectious disease aerobiology Relationship between humidity and influenza A viability in droplets and implications for influenza's seasonality Natural sources and experimental generation of bioaerosols: challenges and perspectives The role of particle size in aerosolised pathogen transmission: a review Concentrations and size distributions of airborne influenza A viruses measured indoors at a health centre, a day-care centre and on aeroplanes Detection and isolation of airborne influenza A H3N2 virus using a sioutas personal cascade impactor sampler Concentration, size distribution, and infectivity of airborne particles carrying swine viruses Aerosolization of particles from a bubbling liquid: characteristics and generator development Design and performance of a single-pass bubbling bioaerosol generator A systematic comparison of four bioaerosol generators: affect on culturability and cell membrane integrity when aerosolizing Escherichia coli bacteria Release of free DNA by membrane-impaired bacterial aerosols due to aerosolization and air sampling Effect of aerosolization and drying on the viability of pseudomonas syringae cells High-flow-rate impinger for the study of concentration, viability, metabolic activity, and ice-nucleation activity of airborne bacteria Host stress and immune responses during aerosol challenge of Brown Norway rats with Yersinia pestis Aerosolisation of Escherichia coli and associated endotoxin using an improved bubbling bioaerosol generator Vesicle-cloaked virus clusters are optimal units for inter-organismal viral transmission The role of jet and film drops in controlling the mixing state of submicron sea spray aerosol particles Development of a strand specific real-time RT-qPCR assay for the detection and quantitation of murine norovirus RNA Assessment of airborne virus contamination in wastewater treatment plants Electrospray versus nebulization for aerosolization and filter testing with bacteriophage particles Collection and measurement of aerosols of viable influenza virus in liquid media in an Andersen cascade impactor An experimental investigation of the performance of a Collison nebulizer generating H1N1 influenza aerosols Gentle sampling of submicrometer airborne virus particles using a personal electrostatic particle concentrator A wind tunnel evaluation of the physical sampling efficiencies of three bioaerosol samplers Evaluation of six inhalable aerosol samplers Biosurfactants change the thinning of contaminated bubbles at bacteria-laden water interfaces Primary biological aerosol particles in the atmosphere: a review Measurement of airborne influenza virus in a hospital emergency department Distribution of airborne influenza virus and respiratory syncytial virus in an urgent care medical clinic Absolute humidity influences the seasonal persistence and infectivity of human norovirus Hydrogen peroxide vapour treatment inactivates norovirus but has limited effect on post-treatment viral RNA levels Hygroscopic growth and water uptake kinetics of two-phase aerosol particles consisting of ammonium sulfate, adipic and humic acid mixtures Determination of 50% endpoint titer using a simple formula Robert Lange is recognized for his contribution to the aerosol particle size measurements and calculations using the experimental setup. Great thanks is given to Per Wollmer, Birgitta Roos, Lennart Bergqvist and Hanna Holstein for their help and enthusiasm in enabling the radioactivity measurements. Thanks also goes to Tobias Svensson for his contributions in the construction of the flow tube. The schematic illustration in The authors declare no competing interests. Correspondence and requests for materials should be addressed to J.L.Reprints and permissions information is available at www.nature.com/reprints.Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. 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