Detection of Influenza A Virus Nucleoprotein Antibodies in Oral Fluid Specimens From Pigs Infected Under Experimental Conditions Using a Blocking ELISA

In commercial swine populations, influenza is an important component of the porcine respiratory disease complex (PRDC) and a pathogen with major economic impact. Previously, a commercial blocking ELISA (FlockChek^™ Avian Influenza Virus MultiS‐Screen^® Antibody Test Kit, IDEXX Laboratories, Inc., Westbrook, ME, USA) designed to detect influenza A nucleoprotein (NP) antibodies in avian serum was shown to accurately detect NP antibodies in swine serum. The purpose of this study was to determine whether this assay could detect NP antibodies in swine oral fluid samples. Initially, the procedure for performing the NP‐blocking ELISA on oral fluid was modified from the serum testing protocol by changing sample dilution, sample volume, incubation time and incubation temperature. The detection of NP antibody was then evaluated using pen‐based oral fluid samples (n = 182) from pigs inoculated with either influenza A virus subtype H1N1 or H3N2 under experimental conditions and followed for 42 days post inoculation (DPI). NP antibodies in oral fluid were detected from DPI 7 to 42 in all inoculated groups, that is, the mean sample‐to‐negative (S/N) ratio of influenza‐inoculated pigs was significantly different (P < 0.0001) from uninoculated controls (unvaccinated or vaccinated‐uninoculated groups) through this period. Oral fluid versus serum S/N ratios from the same pen showed a correlation of 0.796 (Pearson's correlation coefficient, P < 0.0001). The results showed that oral fluid samples from influenza virus‐infected pigs contained detectable levels of NP antibodies for ≥42 DPI. Future research will be required to determine whether this approach could be used to monitor the circulation of influenza virus in commercial pig populations.     

Appearance of reassortant European avian‐origin H1 influenza A viruses of swine in Vietnam

Three subtypes—H1N1, H1N2 and H3N2—of influenza A viruses of swine (IAV s‐S) are currently endemic in swine worldwide, but there is considerable genotypic diversity among each subtype and limited geographical distribution. Through IAV s‐S monitoring in Vietnam, two H1N2 influenza A viruses were isolated from healthy pigs in Ba Ria‐Vung Tau Province, Southern Vietnam, on 2 December 2016. BLAST and phylogenetic analyses revealed that their HA and NA genes were derived from those of European avian‐like H1N2 IAV s‐S that contained avian‐origin H1 and human‐like N2 genes, and were particularly closely related to those of IAV s‐S circulating in the Netherlands, Germany or Denmark. In addition, the internal genes of these Vietnamese isolates were derived from human A(H1N1)pdm09 viruses, suggesting that the Vietnamese H1N2 IAV s‐S are reassortants between European H1N2 IAV s‐S and human A(H1N1)pdm09v. The appearance of European avian‐like H1N2 IAV s‐S in Vietnam marks their first transmission outside Europe. Our results and statistical analyses of the number of live pigs imported into Vietnam suggest that the European avian‐like H1N2 IAV s‐S may have been introduced into Vietnam with their hosts through international trade. These findings highlight the importance of quarantining imported pigs to impede the introduction of new IAV s‐S.     

Bioaerosol and surface sampling for the surveillance of influenza A virus in swine

Influenza A virus in swine is of significant importance to human and veterinary public health. Environmental sampling techniques that prove practical would enhance surveillance for influenza viruses in swine. The primary objective of this study was to demonstrate the feasibility of bioaerosol and surface sampling for the detection of influenza virus in swine barns with a secondary objective of piloting a mobile application for data collection. Sampling was conducted at a large swine operation between July 2016 and August 2017. Swine oral fluids and surface swabs were collected from multiple rooms. Room‐level air samples were collected using four bioaerosol samplers: a low volume polytetrafluoroethylene (PTFE) filter sampler, the National Institute for Occupational Safety and Health's low volume cyclone sampler, a 2‐stage Andersen impactor and/or one high volume cyclonic sampler. Samples were analysed using quantitative RT‐PCR. Data and results were reported using a mobile data application. Eighty‐nine composite oral fluid samples, 70 surface swabs and 122 bioaerosol samples were analysed. Detection rates for influenza virus RNA in swine barn samples were 71.1% for oral fluids, 70.8% for surface swabs and 71.1% for the PTFE sampler. Analysis revealed a statistically significant relationship between the results of the PTFE sampler and the surface swabs with oral fluid results (p < 0.001 and p < 0.01 respectively). In addition, both the PTFE sampler (p < 0.01) and surface swabs (p = 0.03) significantly correlated with, and predicted oral fluid results. Bioaerosol sampling using PTFE samplers is an effective hands‐off approach for detecting influenza virus activity among swine. Further study is required for the implementation of this approach for surveillance and risk assessment of circulating influenza viruses of swine origin. In addition, mobile data collection stands to be an invaluable tool in the field by allowing secure, real‐time reporting of sample collection and results.     

Risk Factors for Exposure to Influenza A Viruses,Including Subtype H5 Viruses,in Thai Free‐Grazing Ducks

Free‐grazing ducks (FGD) have been associated with highly pathogenic avian influenza (HPAI) H5N1 outbreaks and may be a viral reservoir. In July–August 2010, we assessed influenza exposure of Thai FGD and risk factors thereof. Serum from 6254 ducks was analysed with enzyme‐linked immunosorbent assay (ELISA) to detect antibodies to influenza A nucleoprotein (NP), and haemagglutinin H5 protein. Eighty‐five per cent (5305 ducks) were seropositive for influenza A. Of the NP‐seropositive sera tested with H5 assays (n = 1423), 553 (39%) were H5 ELISA positive and 57 (4%) suspect. Twelve per cent (74 of 610) of H5 ELISA‐positive/suspect ducks had H5 titres ≥ 1 : 20 by haemagglutination inhibition. Risk factors for influenza A seropositivity include older age, poultry contact, flock visitors and older purchase age. Study flocks had H5 virus exposure as recently as March 2010, but no HPAI H5N1 outbreaks have been identified in Thailand since 2008, highlighting a need for rigorous FGD surveillance.     

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Influenza A (H1N1) viruses are distributed worldwide and pose a threat to public health. Swine, as a natural host and mixing vessel of influenza A (H1N1) virus, play a critical role in the transmission of this virus to humans. Furthermore, swine influenza A (H1N1) viruses have provided all eight genes or some genes to the genomes of influenza strains that historically have caused human pandemics. Hence, persistent surveillance of influenza A (H1N1) virus in swine herds could contribute to the prevention and control of this virus. Here, we report a novel reassortant influenza A (H1N1) virus generated by reassortment between 2009 pandemic H1N1 viruses and swine viruses. We also found that this virus is prevalent in swine herds in Shandong Province, eastern China. Our findings suggest that surveillance of the emergence of the novel reassortant influenza A (H1N1) virus in swine is imperative.     

Complete genome sequence of a novel influenza A H1N2 virus circulating in swine from Central Bajio region,Mexico

The aim of this study was to perform the complete genome sequence of a swine influenza A H1N2 virus strain isolated from a pig in Guanajuato, México (A/swine/Mexico/GtoDMZC01/2014) and to report its seroprevalence in 86 counties at the Central Bajio zone. To understand the evolutionary dynamics of the isolate, we undertook a phylogenetic analysis of the eight gene segments. These data revealed that the isolated virus is a reassortant H1N2 subtype, as its genes are derived from human (HA, NP, PA) and swine (M, NA, PB1, PB2 and NS) influenza viruses. Pig serum samples were analysed by the hemagglutination inhibition test, using wild H1N2 and H3N2 strains (A/swine/México/Mex51/2010 [H3N2]) as antigen sources. Positive samples to the H1N2 subtype were processed using the field‐isolated H1N1 subtype (A/swine/México/Ver37/2010 [H1N1]). Seroprevalence to the H1N2 subtype was 26.74% in the sampled counties, being Jalisco the state with highest seroprevalence to this subtype (35.30%). The results herein reported demonstrate that this new, previously unregistered influenza virus subtype in México that shows internal genes from other swine viral subtypes isolated in the past 5 years, along with human virus‐originated genes, is widely distributed in this area of the country.     

Identification and genomic characterization of influenza viruses with different origin in Mexican pigs

Swine influenza is a worldwide disease, which causes damage to the respiratory system of pigs. The H1N1 and H3N2 subtypes circulate mainly in the swine population of Mexico. There is evidence that new subtypes of influenza virus have evolved genetically and have been rearranged with human viruses and from other species; therefore, the aim of our study was to identify and characterize the genetic changes that have been generated in the different subtypes of the swine influenza virus in Mexican pigs. By sequencing and analyzing phylogenetically the eight segments that form the virus genome, the following subtypes were identified: H1N1, H3N2, H1N2 and H5N2; of which, a H1N1 subtype had a high genetic relationship with the human influenza virus. In addition, a H1N2 subtype related to the porcine H1N2 virus reported in the United States was identified, as well as, two other viruses of avian origin from the H5N2 subtype. Particularly for the H5N2 subtype, this is the first time that its presence has been reported in Mexican pigs. The analysis of these sequences demonstrates that in the swine population of Mexico, circulate viruses that have suffered punctual‐specific mutations and rearrangements of their proteins with different subtypes, which have successfully adapted to the Mexican swine population.     

Infection Dynamics of Pandemic 2009 H1N1 Influenza Virus in a Two‐Site Swine Herd

Influenza A viruses are common causes of respiratory disease in pigs and can be transmitted among multiple host species, including humans. The current lack of published information on infection dynamics of influenza viruses within swine herds hinders the ability to make informed animal health, biosecurity and surveillance programme decisions. The objectives of this serial cross‐sectional study were to describe the infection dynamics of influenza virus in a two‐site swine system by estimating the prevalence of influenza virus in animal subpopulations at the swine breeding herd and describing the temporal pattern of infection in a selected cohort of growing pigs weaned from the breeding herd. Nasal swab and blood samples were collected at approximately 30‐day intervals from the swine breeding herd (Site 1) known to be infected with pandemic 2009 H1N1 influenza virus. Sows, gilts and neonatal pigs were sampled at each sampling event, and samples were tested for influenza virus genome using matrix gene RRT‐PCR. Influenza virus was detected in neonatal pigs, but was not detected in sow or gilt populations via RRT‐PCR. A virus genetically similar to that detected in the neonatal pig population at Site 1 was also detected at the wean‐to‐finish site (Site 2), presumably following transportation of infected weaned pigs. Longitudinal sampling of nasal swabs and oral fluids revealed that influenza virus persisted in the growing pigs at Site 2 for at least 69 days. The occurrence of influenza virus in neonatal pigs, but not breeding females, at Site 1 emphasizes the potential for virus maintenance in this dynamic subpopulation, the importance of including this subpopulation in surveillance programmes and the potential transport of influenza virus between sites via the movement of weaned pigs.     

MAb‐based competitive ELISA for the detection of antibodies against influenza D virus

Influenza D virus (IDV) was first reported in 2011 in swine in Oklahoma and consequently found in cattle, sheep, and goats across North America and Eurasia. Cattle have been proposed as the natural reservoir. In this study, we developed and validated a MAb‐based competitive ELISA for the detection of antibodies against IDV. Thirty‐one hybridomas specific to IDV were generated using Balb/C mice immunised with purified IDV/Swine/Italy/199724‐3/2015. The specificity of MAbs was determined by comparing their reactivity with the homologous and other influenza A viruses along with additional bovine and swine viruses. A solid‐phase competitive ELISA (IDV‐cELISA) was set up using the partially purified antigen coated to the plate and incubation of two serum dilutions (1/10 and 1/20) followed by addition of a peroxidase‐conjugated MAb as competitor, which had shown wide intratype cross‐reactivity and positivity in HI. To evaluate the diagnostic performances of IDV‐cELISA, we used 884 sera (414 negative and 470 positive) from different species. ROC analyses were performed to enable the selection of best cut‐off value and estimation of diagnostic specificity and sensitivity. The agreement between IDV‐cELISA and HI test was assessed by Cohen's kappa value (κ). The κ analysis showed an almost perfect agreement (κ = 0.93; 95%CI −0.899 to 0.961) between HI test and IDV‐cELISA. ROC analysis showed that IDV‐cELISA was accurate with an area under the curve (AUC) = 0.999, 95% CI 0.993–1.000). A cut‐off value of 65% was selected with Se and Sp values of 99.35 (95% CI 98.1–99.9) and 98.75 (95% CI 97.1–99.6). These results proved excellent diagnostic performances of IDV‐cELISA, which compared to HI presented major advantages, such as suitability for automation, low dependence on individual skills, spectrophotometric reading, and easy interpretation of the results. This assay can be exploited to detect anti‐IDV antibodies in different animal species.     

Expression and Characterization of HA1 Protein of Highly Pathogenic H5N1 Avian Influenza Virus for Use in a Serodiagnostic Assay

The hemagglutinin ectodomain (HA1 subunit) from highly pathogenic avian influenza (HPAI) isolate (A/chicken/Vietnam/14/2005) was cloned and expressed using a baculovirus expression vector. Biosynthesis, glycosylation and secretion of the HA1 proteins, with natural or a melittin signal peptide at the N‐terminus and a six‐histidine (6xHis) tag at the C‐terminus, were examined in insect cells. A 40‐kDa unglycosylated precursor and a fully processed, mature form of the HA1 protein migrated around 52 kDa were detected by SDS‐PAGE and confirmed by Western blot using H5N1‐specific antibody. Treatment of tunicamycin and peptide‐N‐glycosidase F (PNGase F) further revealed that the recombinant HA1 proteins produced in insect cells were indeed glycosylated with N‐linked oligosaccharide side chains. Time‐course experiments showed that substitution of the HA natural sequence with the signal sequence from honeybee melittin promoted a high level of expression and efficient secretion of the HA1. A high yield, 37 μg/ml, of HA1 protein was obtained from recombinant baculovirus‐infected cell culture supernatant. In addition, the cell surface expression of rHA1 was detected by indirect immunofluorescent staining and showed biological activity on hemadsorption assays. Recombinant HA1 protein‐based ELISA was evaluated and appeared to be sensitive and specific for the rapid detection of H5 subtype‐specific antibodies in serum samples. No cross‐reactivity to antibodies from 15 other influenza A subtypes was detected. Taken together, the newly developed recombinant HA1‐based ELISA could offer an alternative to other diagnostic approaches for the specific detection of H5 avian influenza virus infection.     

Unusually High Mortality in Waterfowl Caused by Highly Pathogenic Avian Influenza A(H5N1) in Bangladesh

Mortality in ducks and geese caused by highly pathogenic avian influenza A(H5N1) infection had not been previously identified in Bangladesh. In June–July 2011, we investigated mortality in ducks, geese and chickens with suspected H5N1 infection in a north‐eastern district of the country to identify the aetiologic agent and extent of the outbreak and identify possible associated human infections. We surveyed households and farms with affected poultry flocks in six villages in Netrokona district and collected cloacal and oropharyngeal swabs from sick birds and tissue samples from dead poultry. We conducted a survey in three of these villages to identify suspected human influenza‐like illness cases and collected nasopharyngeal and throat swabs. We tested all swabs by real‐time RT‐PCR, sequenced cultured viruses, and examined tissue samples by histopathology and immunohistochemistry to detect and characterize influenza virus infection. In the six villages, among the 240 surveyed households and 11 small‐scale farms, 61% (1789/2930) of chickens, 47% (4816/10 184) of ducks and 73% (358/493) of geese died within 14 days preceding the investigation. Of 70 sick poultry swabbed, 80% (56/70) had detectable RNA for influenza A/H5, including 89% (49/55) of ducks, 40% (2/5) of geese and 50% (5/10) of chickens. We isolated virus from six of 25 samples; sequence analysis of the hemagglutinin and neuraminidase gene of these six isolates indicated clade 2.3.2.1a of H5N1 virus. Histopathological changes and immunohistochemistry staining of avian influenza viral antigens were recognized in the brain, pancreas and intestines of ducks and chickens. We identified ten human cases showing signs compatible with influenza‐like illness; four were positive for influenza A/H3; however, none were positive for influenza A/H5. The recently introduced H5N1 clade 2.3.2.1a virus caused unusually high mortality in ducks and geese. Heightened surveillance in poultry is warranted to guide appropriate diagnostic testing and detect novel influenza strains.     

Serological evidence of H3N2 canine influenza virus infection among horses with dog exposure

Currently, Canine influenza virus (CIV) H3N2 is continuously circulating in dog populations in China, Korea, and the United States (US). Both influenza SA‐α‐2,3‐Gal and SA‐α‐2,6‐Gal receptors have been observed in the respiratory tracts of both horses and dogs. Hence, the increasing number of CIV H3N2 cases in the world indicates a potential risk for transspecies transmission to horses with dog exposure. Here, a seroepidemiological survey of CIV H3N2 infections in horses was conducted using hemagglutination inhibition (HI), microneutralization (MN) and the chicken embryo neutralization test (CENT). From April 2014 to November 2016, 399 sera from race horses were collected in Guangzhou, Dongguan, Huizhou, and Shenzhen in China. Nine specimens (2.2%, 9/399) were positive for CIV H3N2 with HI titers ≥ 1:20, MN titers ≥ 1:80 and CENT titers ≥ 1:80. Furthermore, these positive horses showed significant correlation with dog exposure, and some dogs (20%, 3/15) from the same riding clubs as the positive horses also possessed antibodies against CIV H3N2. This study is the first to provide seroepidemiological evidence of CIV H3N2 infection in horses with exposure to dogs. Based on these findings, continuous serological and virological surveillance of CIV H3N2 infection among horses is imperative, and further animal experiments should be performed.     

Seroprevalence and Risk Factors for Swine Influenza Zoonotic Transmission in Swine Workers from Northwestern Mexico

Summary A cross‐sectional study was conducted to evaluate the transmission of swine influenza through occupational exposure and to assess some risk factors for zoonotic transmission in workers from commercial farms in Mexico. Seroprevalence to swine influenza subtypes was determined by hemagglutinin inhibition assay and was higher in exposed (E), in comparison with unexposed (UE) participants (P < 0.05). Percentages of seropositivity between UE and E were 28.57% and 19.35% to A/NewCaledonia/20/99 (H1N1), 68.25% and 33.87% to A/Panama/2001/99‐like (H3N2), 1.58% and 12.9% to A/Sw/England/163266/87 (H3N2), respectively. No antibodies were detected against A/Sw/Wisconsin/238/97 (H1N1) in the UE subjects, and only 3.22% were positive in the E group (P < 0.05). A significant association between elevated antibody titres to swine influenza virus (SIV) H3N2 and the exposition to swine [OR 3.05, 95% (CI) 1.65–5.64] and to geographic location [OR 8.15, 95% (CI) 1.41–47.05] was found. Vaccination appeared as a protective factor [OR 0.05, 95% (CI) 0.01–0.52]. Farms with high number of breeding herd were associated with increased anti‐SIV antibodies in the E group [OR 3.98, 95% (CI) 1.00–15.86]. These findings are relevant and support the evidence of zoonoses in swine farms and point out the need to implement preventive measures to diminish the occurrence of the disease and the potential emergence of pathogenic reassortant strains.     

Characteristics of the first H16N3 subtype influenza A viruses isolated in western China

The first documented avian influenza virus subtype H16N3 was isolated in 1975 and is currently detectable in many countries worldwide. However, the prevalence, biological characteristics and threat to humans of the avian influenza virus H16N3 subtype in China remain poorly understood. We performed avian influenza surveillance in major wild bird gatherings across the country from 2017 to 2019, resulting in the isolation of two H16N3 subtype influenza viruses. Phylogenetic analysis showed these viruses belong to the Eurasian lineage, and both viruses presented the characteristics of inter‐species reassortment. In addition, the two viruses exhibited limited growth capacity in MDCK and A549 cells. Receptor‐binding assays indicated that the two H16N3 viruses presented dual receptor‐binding profiles, being able to bind to both human and avian‐type receptors, where GBHG/NX/2/2018(H16N3) preferentially bound the avian‐type receptor, while GBHG/NX/1/2018(H16N3) showed greater binding to the human‐type receptor, even the mice virulence data showed the negative results. Segments from other species have been introduced into the H16N3 avian influenza virus, which may alter its pathogenicity and host tropism, potentially posing a threat to animal and human health in the future. Consequently, it is necessary to increase monitoring of the emergence and spread of avian influenza subtype H16N3 in wild birds.     

Influenza A Virus in Backyard Pigs and Poultry in Rural Cambodia

Surveillance of influenza virus in humans and livestock is critical, given the worldwide public health threats and livestock production losses. Livestock farming involving close proximity between humans, pigs and poultry is often practised by smallholders in low‐income countries and is considered an important driver of influenza virus evolution. This study determined the prevalence and genetic characteristics of influenza A virus (IAV) in backyard pigs and poultry in Cambodia. A total of 751 animals were tested by matrix gene‐based rRT‐PCR, and influenza virus was detected in 1.5% of sampled pigs, 1.4% of chickens and 1.0% of ducks, but not in pigeons. Full‐length genome sequencing confirmed triple reassortant H3N2 in all IAV‐positive pigs and various low pathogenic avian influenza subtypes in poultry. Phylogenetic analysis of the swine influenza viruses revealed that these had haemagglutinin and neuraminidase genes originating from human H3N2 viruses previously isolated in South‐East Asia. Phylogenetic analysis also revealed that several of the avian influenza subtypes detected were closely related to internal viral genes from highly pathogenic H5N1 and H9N2 formerly sequenced in the region. High sequence homology was likewise found with influenza A viruses circulating in pigs, poultry and wild birds in China and Vietnam, suggesting transboundary introduction and cocirculation of the various influenza subtypes. In conclusion, highly pathogenic subtypes of influenza virus seem rare in backyard poultry, but virus reassortment, involving potentially zoonotic and pandemic subtypes, appears to occur frequently in smallholder pigs and poultry. Increased targeted surveillance and monitoring of influenza circulation on smallholdings would further improve understanding of the transmission dynamics and evolution of influenza viruses in humans, pigs and poultry in the Mekong subregion and could contribute to limit the influenza burden.     

One‐Health Simulation Modelling: A Case Study of Influenza Spread between Human and Swine Populations using NAADSM

The circulation of zoonotic influenza A viruses including pH1N1 2009 and H5N1 continue to present a constant threat to animal and human populations. Recently, an H3N2 variant spread from pigs to humans and between humans in limited numbers. Accordingly, this research investigated a range of scenarios of the transmission dynamics of pH1N1 2009 virus at the swine–human interface while accounting for different percentages of swine workers initially immune. Furthermore, the feasibility of using NAADSM (North American Animal Disease Spread Model) applied as a one‐health simulation model was assessed. The study population included 488 swine herds and 29, 707 households of people within a county in Ontario, Canada. Households were categorized as follows: (i) rural households with swine workers, (ii) rural households without swine workers, and (iii) urban households without swine workers. Forty‐eight scenarios were investigated, based on the combination of six scenarios around the transmissibility of the virus at the interface and four vaccination coverage levels of swine workers (0–60%), all under two settings of either swine or human origin of the virus. Outcomes were assessed in terms of stochastic ‘die‐out’ fraction, size and time to peak epidemic day, overall size and duration of the outbreaks. The modelled outcomes indicated that minimizing influenza transmissibility at the interface and targeted vaccination of swine workers had significant beneficial effects. Our results indicate that NAADSM can be used as a framework to model the spread and control of contagious zoonotic diseases among animal and human populations, under certain simplifying assumptions. Further evaluation of the model is required. In addition to these specific findings, this study serves as a benchmark that can provide useful input to a future one‐health influenza modelling studies. Some pertinent information gaps were also identified. Enhanced surveillance and the collection of high‐quality information for more accurate parameterization of such models are encouraged.     

Genetic variability of influenza A virus in pigs at weaning in Midwestern United States swine farms

Suckling piglets play an important role at maintaining influenza A virus (IAV) infections in breeding herds and disseminating them to other farms at weaning. However, the role they play at weaning to support and promote genetic variability of IAV is not fully understood. The objective here was to evaluate the genetic diversity of IAV in pigs at weaning in farms located in the Midwestern USA. Nasal swabs (n = 9,090) collected from piglets in breed‐to‐wean farms (n = 52) over a six‐month period across seasons were evaluated for the presence of IAV. Nasal swabs (n = 391) from 23 IAV‐positive farms were whole‐genome sequenced. Multiple lineages of HA (n = 7) and NA (n = 3) were identified in 96% (22/23) and 61% (237/391) of the investigated farms and individual piglets, respectively. Co‐circulation of multiple types of functional HA and NA was identified in most (83%) farms. Whole IAV genomes were completed for 126 individual piglet samples and 25 distinct and 23 mixed genotypes were identified, highlighting significant genetic variability of IAV in piglets. Co‐circulation of IAV in the farms and co‐infection of individual piglets at weaning was observed at multiple time points over the investigation period and appears to be common in the investigated farms. Statistically significant genetic variability was estimated within and between farms by AMOVA, and varying levels of diversity between farms were detected using the Shannon–Weiner Index. Results reported here demonstrate previously unreported levels of molecular complexity and genetic variability among IAV at the farm and piglet levels at weaning. Movement of such piglets infected at weaning may result in emergence of new strains and maintenance of endemic IAV infection in the US swine herds. Results presented here highlight the need for developing and implementing novel, effective strategies to prevent or control the introduction and transmission of IAV within and between farms in the country.