Results of air filtration to prevent porcine reproductive and respiratory syndrome virus (PRRSV) infection can be of interest for 2 reasons. First, positive results indicate a way to reduce losses and suffering associated with this disease. Second, the results allow for indirect assessment of the relative importance of aerosol transmission in the epidemiology of the disease. If after air filtration the number of cases was reduced by a large percentage in the absence of significant improvements in other biosecurity measures, it would mean that aerosol transmission is responsible for a large percentage of PRRSV cases. This commentary will summarize results obtained with different air filtration systems in France and North America. Studies published within the last 10 years were selected so that relatively recent data were considered.
High-efficiency particulate air filters
High-efficiency particulate air (HEPA) filters are expensive, but they can prevent the passage of at least 99.97% of particles of any size.1 Their use is often limited to herds that are particularly important, like boar studs, nucleus, or multiplier herds. These filters have been used mostly in France, normally coupled with positive-pressure ventilation. The site in France where this system was first used for swine was the Outil expérimental de l’ANSES, laboratoire de Ploufragan (formerly called Station de Pathologie Porcine de Ploufragan). This experimental unit is where many of the French studies on swine infectious diseases have been conducted.2 This site includes a small specific-pathogen-free herd protected by air filtration since its installment in 1979. The site is in Brittany, the area of France where swine production is the most intensified. After 42 years in operation, the herd has remained negative for pathogens like PRRSV, influenza A virus-swine, pseudorabies virus, porcine respiratory coronavirus, and Mycoplasma hyopneumoniae, all of which are known to be transmissible by aerosol.3,4
This filtration technology was later used in farms of importance for different companies. Table 1 shows the number of farms that were equipped with this technology since 1995, the number of years prior to 2022 that the farm was at risk, and the number of PRRSV cases over the years.
| Installation year | No. of farms | Farm years at risk | PRRSV cases |
| 1995 | 1 | 27 | 0 |
| 1996 | 2 | 52 | 0 |
| 1997 | 1 | 25 | 0 |
| 1998 | 4 | 96 | 2 |
| 1999 | 3 | 69 | 0 |
| 2000 | 2 | 44 | 0 |
| 2001 | 2 | 42 | 0 |
| 2002 | 2 | 40 | 0 |
| 2003 | 3 | 57 | 0 |
| 2005 | 2 | 34 | 0 |
| 2007 | 2 | 30 | 0 |
| 2009 | 3 | 39 | 0 |
| 2010 | 1 | 12 | 0 |
| 2011 | 3 | 33 | 0 |
| 2012 | 3 | 30 | 0 |
| 2013 | 2 | 18 | 0 |
| 2014 | 2 | 16 | 0 |
| 2015 | 7 | 49 | 0 |
| 2016 | 4 | 24 | 0 |
| 2017 | 1 | 5 | 0 |
| 2018 | 1 | 4 | 0 |
| 2019 | 2 | 6 | 0 |
| Total | 53 | 752 | 2 |
| Cases per farm year at risk | 0.0027 | ||
| Mean number of filtration years per farm: 14.2 | |||
Fifty-three farms were equipped with a HEPA filtration system since 1995, with an average filtration duration of 14.2 years. Thirty-seven of the farms were sow sites of which 32 were farrow-to-finish operations on the same site, 12 were boar studs, and 4 were finishing sites. Sow sites had between 150 and 1000 sows and boar studs had between 32 and 300 boars. Over the years, 2 farms originally filtered in 1998 broke with PRRSV, one farm in 2006 and the other in 2012. In both cases the epidemiological investigation concluded that a biosecurity breach was likely responsible for the infections. All farms have remained negative for Mycoplasma hyopneumoniae, another significant pathogen present in most countries including France.
A French company with a swine farm in China equipped with this type of system has remained negative for PRRSV since it was populated in 2016 (V. Cousin, unpublished data). Quebec, Canada has 5 sites that are equipped with a HEPA filtration system, 4 boar studs and 1 farrow-to-finish operation. The first systems were installed in 2003, and none have yet to become infected with PRRSV (R. Desrosiers, unpublished data). When considering the proportional size of its swine industry, few farms are equipped with a HEPA filtration system in the United States. One veterinary practitioner consults with 6 boar studs that are equipped with HEPA filters, the first installed in 2008. One farm broke with PRRSV twice. The investigation revealed that the filtration system had a bypass on a hand-made duct that allowed unfiltered air to be introduced into the barn. The farm has remained PRRSV negative since the problem was fixed in 2019, and none of the other 5 boar studs have broken with the disease. (D. Reicks, DVM, email, July 2021). Considering the results obtained in France, China, Quebec, and the United States, 95.4% (62 of 65) of the farms where this system was used have remained PRRSV negative. If the boar stud with the faulty system is removed from the list, then none of the remaining 64 farms have broken with PRRSV since 2012.
Other filtration systems
Most of the air filtration systems installed in the United States use filters with minimum efficiency rating values (MERV) of 14, 15, or 16. These systems are predicted to respectively prevent introduction of 75%, 85%, and 95% or more of particles between 0.3 and 1.0 micron.5 Also, some farms are only filtering air during the cooler times of the year when PRRSV outbreaks are more frequent. Most farms initially used a negative-pressure ventilation system, but positive-pressure ventilation has gained popularity in recent years.6 An advantage of positive-pressure ventilation is that, if functioning properly, unfiltered air is not likely to be introduced into the barn through various openings. Many studies have evaluated the results obtained with air filtration, but often without specifying the type of ventilation system, the MERVs of the filters used, and whether they were filtered all year long. Table 2 summarizes the results obtained in studies conducted over the last 10 years.
| Reference | No. Farms; period involved | Results |
| Havas et al,7 2021 | Not specified; not specified | 95% lesser odds of being PRRSV infected if filtered |
| Feder,8 2021 | 85 farms; not specified | More than 3 times less PRRSV cases after filtration |
| Moeller et al,9 2020 | 208 farms; not specified | Odds of PRRSV cases at 0.0992 if filtered vs unfiltered |
| Silva et al,10 2019 | 11 farms in case & control groups; 2012-2017 | Air filtration not ranked among top predictors for PRRSV breaks |
| Vilalta et al,11 2018 | 58 farms; 2009-2018 | Risk of breaking with PRRSV decreased by half after filtration |
| Thomas,6 2018 | 27 farms; 18 months | PRRSV risk reduced 4.3 times after filtration |
| Tousignant,12 2015 | 10 in 2005 up to 119 in 2014; 2005-2014 | Incidence of PRRSV cases across all farms in the data set averaged 6% per year |
| Reicks,13 2015 | 25 boar studs; 4.1 years before and 7.7 years after | Incidence per year went from 14.4% to 1.0% after filtration |
| Reicks,14 2014 | 93 farms; 4.2 years before and 4.8 years after | New infections per year went from 52.5% to 11.3% after filtration |
| Alonso et al,15 2013 | 37 farms; 7 years | Filtration reduced risk of infection by 80% |
| Dee et al,16 2012 | 24 farms; 2005-2012 | From 1.23 cases per herd year before to 0.17 cases per herd year after filtration |
Only one study did not report a major beneficial impact from filtration. Silva et al10 used machine learning algorithms to identify key biosecurity practices and factors associated with breeding herds reporting PPRSV outbreaks. They concluded that air filtration was not ranked among the top predictors for PRRSV outbreaks and suggested this could be due to the percentage of farms that reported air filtration between groups (11 of 50 farms that became PRRSV positive and 11 of 34 that remained uncontaminated). The Tousignant12 study evaluated the results obtained with filtered farms, which had an average PRRSV incidence of 6% per year but did not evaluate results from unfiltered farms. The Morrison Swine Health Monitoring Project (MSHMP) tracks disease occurrence on a subset of US sow herds. The number of herds in the subset has changed over time and in recent years represented approximately 50% of the US sow inventory. Data from this project showed that 20.8% to 39.2% of sow herds reported a PRRSV break each year between 2009 and 2021 (MSHMP, email, December 2021). That is 3.5 to 6.5 times more than was observed in filtered farms of the Tousignant study.12
In the other 9 studies, the number of PRRSV breaks was reduced 2- to 14.4-fold with filtration. The Havas et al7 study did not compare herds in terms of breaks, but in terms of being infected with PRRSV or not. The odds of being positive for PRRSV were reduced by 95% with filtration.
Discussion
The possibility for PRRSV to be transmitted between farms by aerosol has been a controversial topic for many years. In 1999, it was proposed in a popular newsletter that more and more epidemiological evidence suggested that PRRSV could be transmitted between farms by aerosol.17 This created some turmoil because up until then, and for years to come, it was not shown to be possible to infect pigs with PRRSV by aerosol over a distance greater than 2.5 m.18-20 Different researchers expressed opposite views in what was sometimes referred to as the aerosol debate.3 In 2004 and 2005, published studies from different countries and local field observations strongly supporting aerosol transmission of different swine pathogens, including PRRSV, were reviewed.3,4 Among others, these reviews mentioned the impressive results obtained with air filtration in France. In 2009, Pitkin et al21 proved using a regional production model that aerosol transmission of the virus over 120 m could occur repeatedly and confirmed that air filtration was effective at preventing this type of contamination. Since then, different studies have suggested that not only is aerosol transmission possible between farms, but it could even be among the main modes by which the virus is introduced into breeding herds.
The results included in Table 2 would support that there are situations where air filtration makes a large difference in the incidence of PRRSV outbreaks. A frequent and sensible argument to explain the positive results obtained with air filtration is that when installed, other biosecurity measures may also be improved contributing to the apparent positive filtration impact. While this is a possibility, the importance of that beneficial impact is unknown. Given the losses often associated with PRRSV, major efforts to improve biosecurity measures have already been made for many years, whether farms were filtered or not. Furthermore, in a comparison of 25 boar studs, Reicks13,22 stated that the percentage of breaks per year went from 14.4% before filtration to 1.0% after it was implemented with no changes in biosecurity. Thus, the improvement in PRRSV incidence in that case could be attributed solely to filtration, which suggests that most of the breaks prior to filtration were associated with aerosol transmission. Similarly in another US study, Alonso et al15 concluded that air filtration led to an approximately 80% reduction in risk of novel PRRSV introduction indicating that approximately four-fifths of PRRSV outbreaks may be attributable to aerosol transmission on large sow farms with good biosecurity in swine-dense regions. The authors reported that while unable to assess standards of external biosecurity in their study farms, this concern was mitigated by the relatively uniform veterinary oversight across all of them. Finally, Dee et al16 reported in one part of their study that the odds for a new PRRSV infection in a nonfiltered breeding herd was 8.03 times higher than in a filtered breeding herd. The authors mentioned that the selected herds used industry standard biosecurity practices and were exposed to comparable conditions suggesting that filtration was the most important difference between the groups.
The results obtained with air filtration in France were and have remained impressive. In one of the first reports on its efficacy, Lecarpentier et al23 described 11 farms equipped with such a system that were owned by the same company. The first filtration was installed in 1996, two were installed in 2002, and the others installed between 1998 and 2000. Seven of the 11 farms had been contaminated with PRRSV prior to filtration. None of them became infected prior to 2004, when the study was reported. Ten of these 11 herds were in Brittany, the area in France with the highest pig density. However, as previously mentioned, the main system used in France is different than those used in most cases in the United States.
Dee et al24 showed that the efficacy of various systems could vary. When comparing HEPA filters to a MERV 15 system, only the former prevented infection of pigs in all replicates (76 of 76) while the latter did not in 2 of them (74 of 76). More recently Batista25 evaluated the efficacy of different filters (MERV 14, MERV 16, and antimicrobial filters) to block the passage of PRRSV, influenza A virus-swine, and Streptococcus thermophilus (as a model for Streptococcus suis). The author concluded that the MERV 16 filters had the highest capture efficiencies. When considering their ability to prevent airborne PRRSV transport, Dee et al26 showed that efficacy differences may be found with systems from different companies having the same theoretical MERV values. Finally, it was also suggested that some filtration systems do not maintain their efficacy over time as well as others.6 Thus, it is important when evaluating results obtained with air filtration to consider the specifics of each filtration system used.
Dee et al16 reported that 24 farms had an average of 1.23 cases per farm year at risk before filtration. It greatly improved to 0.17 cases per farm year at risk following filtration with MERV 14 or 16 filters. The 53 farms equipped with HEPA filters in France had 0.0027 cases per farm year at risk, or 63 times less. More information would be needed to determine to what level comparison between the US and French results can be made. Different factors would need to be evaluated, including the respective biosecurity measures observed on farms, the size of the farms, the infection pressure from the neighboring herds, the aerosol transmissibility of the strains, and the climatic conditions. Nevertheless, the magnitude of difference in the results obtained as well as the theoretical superiority of HEPA filters seem to leave little doubt on the fact that better results can be obtained with these filters.
There is no more debate over the possibility for PRRSV to be transmitted between farms by aerosol. Today the question is how frequently and over what possible distances aerosol transmission occurs. The results obtained with air filtration in different countries suggest that there are situations, particularly in hog-dense areas, where viral aerosol transmission could be the most important way of introduction into breeding herds. This would align with the relative inefficacy of other significant biosecurity efforts that have been applied to control it.27
Nevertheless, there are clearly other ways by which the PRRSV can be introduced into swine herds, and not all studies have shown that aerosol or local transmission had an important role in the epidemiology of PRRSV.28-32 Looking at spatial and temporal patterns of PRRSV genotypes, Rosendal et al28 concluded that there was no strong evidence that aerosol transmission was occurring in Ontario. Similarly, Kwong et al32 reported that the 3 relatively most important factors for the spread of a specific genotype in that province were sharing the same herd ownership, gilt source, and market trucks. Spatial proximity could not be identified as an important contributor to spread. In a review on the topic, Arruda et al31 reported that aerosol transmission of the PRRSV was possible, but further studies were needed to determine if it was a frequent event or not. While most studies where air filtration was evaluated suggest that aerosol contamination is frequent, the relative importance of that transmission route is still debated.
Because air filtration systems currently used are expensive, another question remaining is the distance over which the virus can travel by aerosol to infect herds. Quantifying that distance would help to determine at what point investment in filtration or in future methods found to prevent aerosol contamination may be justified.
Finally, not all air filtration systems are created equal as some are more effective than others. Efficient prevention of aerosol contamination can allow a farm to remain negative for PRRSV and other airborne pathogens on a long-term basis.
Implications
- Not all air filtration systems are created equal.
- Being PRRSV negative long-term is possible, even in hog-dense areas.
- There are situations where aerosol is the most frequent contamination source.
Acknowledgments
The authors would like to acknowledge Dr Darwin Reicks for providing supplementary information on his research and results with HEPA filters used on farms he consults with.
Conflict of interest
None
Disclaimer
Scientific manuscripts published in the Journal of Swine Health and Production are peer reviewed. However, information on medications, feed, and management techniques may be specific to the research or commercial situation presented in the manuscript. It is the responsibility of the reader to use information responsibly and in accordance with the rules and regulations governing research or the practice of veterinary medicine in their country or region.
References
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