Materiały źródłowe

• #1 H1N1 Influenza – StatPearls – NCBI Bookshelf

  https://www.ncbi.nlm.nih.gov/books/NBK513241/

  H1N1 influenza was first isolated from pigs in the 1930s by researchers in the United States and was subsequently recognized by pork producers and veterinarians as a cause of influenza infections in pigs worldwide. […] The virus can potentially cause cross-species transmission through viral reassortment. Selection pressure from human populations immune to established strains of influenza can result in changes in antigenic structure over time to evade host immune responses, also known as antigenic drift. […] Significant shifts in the envelope proteins, known as antigenic shifts, can lead to the emergence of new influenza strains capable of evading the host immune response and facilitating human-to-human transmission in previously susceptible populations. […] The 2009 H1N1 pandemic, originating in Mexico, resulted from the combination of multiple strains, including Eurasian avian-like H1N1, avian H1N1, and a previously reassorted lineage consisting of avian H1N1, human H3N2, and swine influenza viruses.

• #2 H1N1 Influenza – StatPearls – NCBI Bookshelf

  https://www.ncbi.nlm.nih.gov/books/NBK513241/

  Revised estimates from the 2009 H1N1 influenza pandemic indicated 151,700 to 575,500 respiratory and cardiac deaths occurred during the first 12 months of the pandemic, with up to 24% of the global population estimated to have been infected based on seroprevalence studies. […] Influenza strains, including H1N1, are known to transmit between pigs and humans frequently, but human-to-human transmission is uncommon. […] The potential retention of influenza virus strains in swine after these strains disappear in the human population essentially makes pigs a reservoir where swine influenza viruses can persist. […] These strains can later emerge to reinfect human populations following reassortment, waned immunity, or a combination of both. As a result, new variants can continue to develop with increased genetic diversity, resulting in new threats to susceptible human populations.

• #3 Influenza pandemic (H1N1) of 2009 | Causes, Symptoms & Treatment | Britannica

  https://www.britannica.com/event/influenza-pandemic-H1N1-of-2009

  influenza pandemic (H1N1) of 2009, the first major influenza outbreak in the 21st century, noted for its rapid global spread, which was facilitated by an unusually high degree of viral contagiousness. […] The calculation of accurate global figures by entities such as the World Health Organization (WHO) was precluded by case underreporting and difficulty in obtaining samples from affected individuals, particularly in developing countries. […] The H1N1 virus was most lethal in individuals affected by chronic disease or other underlying health conditions. […] The virus was passed from human to human primarily through inhalation of infectious particles or contact with an infected individual or a contaminated surface. […] The H1N1 virus of 2009 was highly contagious; between 22 and 33 percent of people who came into contact with an infected individual became infected themselves.

• #4 Swine Flu (H1N!): Pandemic, Vaccine, Causes, Symptoms, Treatment & Contagious

  https://www.medicinenet.com/swine_flu/article.htm

  Swine flu is a respiratory disease caused by influenza viruses that infect the respiratory tract of pigs and result in a barking cough, decreased appetite, nasal secretions, and listless behavior; the virus can be transmitted to humans. […] The April 2009 swine flu outbreak (pandemic) was due to infection with the H1N1 virus and was first observed in Mexico. […] Swine influenza is transmitted from person to person by inhalation or ingestion of droplets containing the virus from people sneezing or coughing; it is not transmitted by eating cooked pork products. […] The incubation period for swine flu is about one to four days, with the average being two days; in some people, the incubation period may be as long as about seven days in adults and children. […] The contagious period (human-to-human viral infection) for swine influenza in adults usually begins one day before symptoms develop in an adult and it lasts about five to seven days after the person becomes sick.

• #5 Influenza surveillance in pigs: balancing act between broad diagnostic coverage and specific virus characterization | Porcine Health Management | Full Text

  https://porcinehealthmanagement.biomedcentral.com/articles/10.1186/s40813-024-00367-9

  Swine influenza A virus (swIAV) is an important pathogen in swine causing respiratory disease and reproductive disorders. […] The capability of swIAVs to overcome the species barrier in combination with genetic shift and drift, due to coinfections with different swIAV subtypes might lead to the emergence of new virus variants with pandemic potential. […] Recent publications indicate an increasing prevalence of swIAV infected swine farms and an extending virus variability in Europe within the last decade. […] This is particularly caused by the emergence of a new human pandemic H1N1 strain in 2009 and its immediate reverse zoonotic transmission into swine populations worldwide where it reassorted extensively with circulating endemic swIAVs. […] The traditional diagnostic approach to identify swIAV in pig farms includes indirect (ELISA, hemagglutination inhibition) or direct (RT-qPCR, virus isolation, next generation sequencing) methods.

• #6 Pandemic (H1N1) 2009 Surveillance for Severe Illness and Response, New York, New York, USA, April–July 2009

  https://pmc.ncbi.nlm.nih.gov/articles/PMC3298321/

  Health departments need the capacity to rapidly expand and modify surveillance during a changing outbreak. […] This surveillance identified 996 hospitalized patients with confirmed or probable pandemic (H1N1) 2009 virus infection from April 24 to July 7; fifty percent lived in high-poverty neighborhoods. […] Surveillance data were critical in guiding the DOHMH response. […] The DOHMH experience during this outbreak illustrates the need for the capacity to rapidly expand and modify surveillance to adapt to changing conditions. […] The agency also prioritized identification and diagnostic testing of patients with severe or fatal cases of ILI in hospitals or clusters of those with ILI in schools and other congregate settings; this surveillance was essential because evidence of severe pandemic (H1N1) 2009 would have prompted more aggressive public health control measures.

• #7 Pandemic (H1N1) 2009 Surveillance for Severe Illness and Response, New York, New York, USA, April–July 2009

  https://pmc.ncbi.nlm.nih.gov/articles/PMC3298321/

  Surveillance and reporting requirements were modified when it became clear that circulation of pandemic (H1N1) 2009 was citywide, but surveillance for deaths and hospitalized cases continued to help officials assess the severity and at-risk groups for pandemic (H1N1) 2009, and the resulting information helped inform DOHMH planning and response to this new virus. […] Approximately half of hospitalized patients lived in a high-poverty neighborhood; this association between poverty and severe illness has been reported for seasonal influenza. […] Future studies should assess poverty status and its relationship to severe influenza illness. […] Surveillance data from the spring outbreak informed NYC planning and response to pandemic (H1N1) 2009 during the 2009-10 fall and winter influenza season. […] Surveillance guided and informed the NYC response to pandemic (H1N1) 2009, and this experience will help NYC plan a response to future epidemics.

• #8 Factsheet on swine influenza in humans and pigs

  https://www.ecdc.europa.eu/en/swine-influenza/factsheet

  Evidence of person-to-person spread of swine-origin influenza viruses (SIVs) is very limited and most swine-to-human transmissions have been epidemiologically dead-end events, i.e. onward transmissions are very rare. […] Human infections with swine influenza have been sporadically detected (or at least published in the literature) since the late 1950s. […] Sporadic transmission events of swine influenza viruses to humans have been reported in Europe and are described in the monthly Communicable Threat Reports (CDTR) as well as in the annual epidemiological zoonotic influenza reports. […] There are sporadic reports of human infections with swine influenza viruses, mainly in people who had direct contact with infected pigs. […] The epidemiology and virology of SIVs in Europe and the United States seem to be quite different.

• #9 Factsheet on swine influenza in humans and pigs

  https://www.ecdc.europa.eu/en/swine-influenza/factsheet

  Swine influenza in pigs is not notifiable at the EU level and no routine surveillance in pig populations is in place. […] Surveillance is dependent on individual national or supranational initiatives to analyse and adapt the available swine influenza vaccines. […] Swine influenza is among the 10 priority zoonotic diseases for which surveillance strategies have been proposed by EFSA. […] The A(H1N1)pdm09 influenza virus from 2009 contained genes from pig, bird and human influenza viruses, in a combination that had not been reported before in any part of the world. […] Following the emergence of the 2009 pandemic, this virus was also isolated from pigs in multiple areas of the world (including Europe), and it is currently circulating in pigs in several European countries. […] The transmission of these reassortant viruses to humans could then result in the introduction of novel viruses into the human population.

• #10 Influenza in Swine | HomeA Lock

  https://www.usda.gov/farming-and-ranching/animal-science/one-health/influenza-swine

  Influenza is a respiratory disease caused by type A influenza viruses that regularly cause outbreaks in pigs. Influenza is present at low levels in pigs throughout the world, and is monitored by the voluntary USDA Swine Influenza Surveillance Program, although it is not a reportable or regulated disease. […] The main influenza viruses circulating in U.S. pigs in recent years are H1N1, H1N2 and H3N2. […] Health organizations use the term „variant” to refer to viruses that are genetically different from what is usually isolated from humans. […] In 2011, a new variant virus was detected that was an influenza A (H3N2) virus with genes from avian, swine and human viruses. […] This 2009 H1N1 M gene may allow these H3N2 viruses in swine to be more transmissible from pigs to people and possibly from person to person.

• #11 Alert but not alarmed: what to make of new H1N1 swine flu with ‘pandemic potential’ found in China – Child Health Research Centre – University of Queensland

  https://child-health-research.centre.uq.edu.au/article/2020/07/alert-not-alarmed-what-make-new-h1n1-swine-flu-%E2%80%98pandemic-potential%E2%80%99-found-china

  Researchers have found a new strain of flu virus with pandemic potential in China that can jump from pigs to humans, triggering a suite of worrying headlines. […] But its important to understand that, as yet, there is no evidence of human-to-human transmission of this particular virus. […] China has a wonderful influenza surveillance system across all its provinces. […] systematic surveillance of influenza viruses in pigs is essential for early warning and preparedness for the next potential pandemic. […] In their influenza virus surveillance of pigs from 2011 to 2018, the researchers found what they called a recently emerged genotype 4 (G4) reassortant Eurasian avian-like (EA) H1N1 virus. […] Importantly, the researchers found no evidence yet of human-to-human transmission. […] In summary, this virus has been around a few years, we know it can jump from pigs to humans and it ticks all the boxes to be what infectious disease scholars call a PPP a potential pandemic pathogen.

• #12 Swine Flu Outbreaks in 2023 Illustrate Reality of Zoonotic Influenza

  https://globalbiodefense.com/2024/03/31/swine-flu-outbreaks-in-2023-illustrate-reality-of-zoonotic-influenza/

  The diversity of zoonotic influenza viruses that caused human infections in 2023 is alarming and underscores the need to bolster surveillance and pandemic preparedness. […] On 7 June 2023, WHO was notified of a fatal laboratory-confirmed human case of infection with a swine-origin influenza A(H1N1) variant (v) virus in the inner state of Paran. […] On 2 September 2023, WHO was notified of a laboratory-confirmed human case of infection with a swine-origin influenza A(H1N1) variant (v) virus in the province of North Brabant, Netherlands. […] This was the first human infection caused by influenza A(H1N1)v virus reported in the Netherlands in 2023. […] On 25 November 2023, WHO was notified of a human case of swine-origin influenza A(H1N2) virus infection. […] This case was identified after a respiratory sample was collected and further analyzed as part of routine surveillance of respiratory illnesses. […] Surveillance of swine influenza virus in Hanoi, Vietnam, during 20132019 revealed gene pool enrichment from imported swine from Asia and North America and showed long-term maintenance, persistence, and reassortment of virus lineages.

• #13 H1N1 Pandemic

  https://knowledge.aidr.org.au/resources/health-h1n1-pandemic/

  In April 2009, a new strain of influenza, a virus called 'H1N1 2009 influenza’, was identified in Mexico. […] The World Health Organisation declared it a pandemic in June 2009. […] The Department of Health and Ageing reported that there were 44,403 confirmed cases of swine flu in Australia since May 2009, including 6767 in 2010. […] The Centers for Disease Control and Prevention estimate that globally there were approximately 284,500 fatalities as a result of the pandemic, with 59 per cent of the deaths occurring in south-east Asia and Africa, and 80 per cent of the victims under 65 years of age.

• #14

  https://journals.lww.com/lungindia/fulltext/2011/28010/an_insight_into_the_swine_influenza_a__h1n1__virus.9.aspx

  WHO declares on June 11, 2009, that H1N1 (Swine-influenza A) is pandemic. There have been nearly 30,000 confirmed H1N1 cases across 74 countries. […] As per the latest report of the Ministry of Health and Family Welfare, death from swine flu has reached to 1235. Around 12,3397 people have been tested in India as on February 1, 2010. In India, 23.3% of people who have tested for swine flu are found suffering from swine flu. Also around 4% of people who have tested positive for swine flu have died and could not be saved in India. […] Swine-origin influenza A (H1N1) virus in humans have been identified in swine in the United States since 1998, and 12 cases of human infection with such viruses were identified in the United States from 2005 through 2009. As of May 5, 2009, a total of 642 cases of human infection with a swine-origin influenza A (H1N1) virus have been identified in the United States, and other additional cases have been identified in Mexico, Canada, and South-East Asia.

• #15 Swine influenza (swine flu) – AGES

  https://www.ages.at/en/human/disease/pathogens-from-a-to-z/swine-influenza-swine-flu

  As part of the EU project „United4Surveillance”, AGES is conducting pilot studies (2023-2025) on different surveillance approaches to monitor the spread of swine influenza viruses. In addition, some European initiatives aim to improve public awareness of zoonotic influenza (transmission of influenza viruses between animals and humans) and to establish European networks for the surveillance of swine influenza. In 2022, a European Swine Influenza Network (ESFLU) was established with the aim of setting up an interdisciplinary European network for the swine influenza A virus. The aim is to improve the exchange of information, awareness-raising and global surveillance in preparation for a pandemic.

• #16 2009 swine flu pandemic – Wikipedia

  https://en.wikipedia.org/wiki/2009_swine_flu_pandemic

  The number of lab-confirmed deaths reported to the WHO is 18,449 and is widely considered a gross underestimate. […] The WHO collaborated with the US Centers for Disease Control and Prevention (USCDC) and Netherlands Institute for Health Services Research (NIVEL) to produce two independent estimates of the influenza deaths that occurred during the global pandemic using two distinct methodologies. […] The 2009 H1N1 flu pandemic is estimated to have actually caused about 284,000 (range from 150,000 to 575,000) excess deaths by the WHO-USCDC study and 148,000-249,000 excess respiratory deaths by the WHO-NIVEL study. […] A study done in September 2010 showed that the risk of serious illness resulting from the 2009 H1N1 flu was no higher than that of the yearly seasonal flu. […] The pandemic began to taper off in November 2009, and by May 2010, the number of cases was in steep decline.

• #17 2009 swine flu pandemic – Wikipedia

  https://en.wikipedia.org/wiki/2009_swine_flu_pandemic

  According to WHO statistics (as of July 2010), the virus had killed more than 18,000 people since it appeared in April 2009; however, they state that the total mortality (including deaths unconfirmed or unreported) from the H1N1 strain is „unquestionably higher”. […] The initial outbreak received a week of near-constant media attention. […] Epidemiologists cautioned that the number of cases reported in the early days of an outbreak can be very inaccurate and deceptive, due to several causes, among them selection bias, media bias and incorrect reporting by governments. […] The WHO stated in 2010 that total mortality (including unconfirmed or unreported deaths) from H1N1 flu was „unquestionably higher” than their own confirmed death statistics.

• #18 Swine Influenza – Extension Disaster Education Network

  https://extensiondisaster.net/hazard-resources/agricultural-zoonotic/swine-influenza/

  Swine Influenza is a respiratory disease of pigs caused by Influenza A viruses. Swine influenza viruses circulate among swine throughout the year, but most outbreaks occur during the late fall and winter months similar to influenza outbreaks in humans. […] The 2009 H1N1 virus is a triple reassortant virus for which there is little or no immunity, there is sustained human-to-human transmission, and rapid worldwide spread. June 2009, the World Health Organization (WHO) declared 2009 H1N1 a pandemic influenza. […] The United States Department of Agriculture (USDA) has a Swine Influenza Virus (SIV) surveillance program. Surveillance is aimed to identify the H1N1 strain as well as other non-typical strains of SIV in swine. The immediate goals of the surveillance program are to: Determine if the H1N1 virus strain currently exists in U.S. swine; If the H1N1 strain is present, determine the distribution to inform further policy decisions; Detect other novel influenza virus strains in swine in a timely manner; and Determine genetic characteristics of novel viruses necessary for vaccine and diagnostics development.

• #19 AP Examines H1N1 Surveillance By U.S., WHO | KFF

  https://www.kff.org/news-summary/ap-examines-h1n1-surveillance-by-u-s-who/

  The Associated Press examines how the decision by U.S. health officials to stop counting new cases of H1N1 (swine flu) in July has complicated the governments ability to assess groups particularly hard hit by the virus. The Centers for Disease Control and Prevention is relying on a patchwork system of gathering death and hospitalization numbers. Some states are reporting lab-confirmed cases. Others report illnesses that could be the new swine flu, seasonal flu or some other respiratory disease, the news service writes. […] The World Health Organization also stopped counting cases in July, after deciding that tracking individual swine flu cases was too overwhelming for countries where the virus was spreading widely, the AP writes. The WHO has continued to update swine flu reports, but with the disclaimer that since countries are no longer required to test and report cases, WHOs numbers underestimate (Stobbe, 10/9).

• #20

  https://www.who.int/emergencies/situations/influenza-a-(h1n1)-outbreak

  Before the H1N1 pandemic in 2009, the influenza A(H1N1) virus had never been identified as a cause of infections in people. […] After early reports of influenza outbreaks in North America in April 2009, the new influenza virus spread rapidly around the world. […] By the time WHO declared a pandemic in June 2009, a total of 74 countries and territories had reported laboratory confirmed infections. […] The new virus also led to patterns of death and illness not normally seen in influenza infections. […] The H1N1 (2009) virus continues to circulate as a seasonal virus and is included in the vaccines against seasonal influenza.

• #21 Weekly US Influenza Surveillance Report: Key Updates for Week 17, ending April 26, 2025 | FluView | CDC

  https://www.cdc.gov/fluview/surveillance/2025-week-17.html

  Seasonal influenza activity continues to decline. […] This season is classified as a high severity season overall and for all age groups (children, adults, older adults) and is the first high severity season since 2017-2018. […] Of the 200 influenza A viruses subtyped during Week 17, 135 (67.5%) were influenza A(H1N1)pdm09. […] CDC estimates that there have been at least 47 million illnesses, 610,000 hospitalizations, and 26,000 deaths from flu so far this season. […] Twelve pediatric deaths associated with seasonal influenza virus infection were reported this week, bringing the 2024-2025 season total to 216 pediatric deaths. […] The cumulative hospitalization rate observed in Week 17 was 127.4 per 100,000 population, which is the highest cumulative hospitalization rate for all seasons since 2010-2011.

• #22 Weekly US Influenza Surveillance Report: Key Updates for Week 17, ending April 26, 2025 | FluView | CDC

  https://www.cdc.gov/fluview/surveillance/2025-week-17.html

  Among those with influenza A subtype information, 6,764 (58.4%) had A(H1N1) pdm09. […] A total of 216 influenza-associated pediatric deaths occurring during the 2024-2025 season have been reported to CDC. This number of pediatric deaths exceeds the previous high reported for a regular (non-pandemic) flu season.

• #23 2009 swine flu pandemic – Wikipedia

  https://en.wikipedia.org/wiki/2009_swine_flu_pandemic

  The 2009 swine flu pandemic, caused by the H1N1/swine flu/influenza virus and declared by the World Health Organization (WHO) from June 2009 to August 2010, was the third recent flu pandemic involving the H1N1 virus. […] The first identified human case was in La Gloria, Mexico. […] The virus appeared to be a new strain of H1N1 that resulted from a previous triple reassortment of bird, swine, and human flu viruses which further combined with a Eurasian pig flu virus, leading to the term „swine flu”. […] Unlike most strains of influenza, the pandemic H1N1/09 virus did not disproportionately infect adults older than 60 years; this was an unusual and characteristic feature of the H1N1 pandemic. […] Some studies estimated that the real number of cases including asymptomatic and mild cases could be 700 million to 1.4 billion people or 11 to 21 percent of the global population of 6.8 billion at the time.

• #24 Influenza A virus subtype H1N1 – Wikipedia

  https://en.wikipedia.org/wiki/Influenza_A_virus_subtype_H1N1

  On 11 June 2009, the WHO declared an H1N1 pandemic, moving the alert level to phase 6, marking the first global pandemic since the 1968 Hong Kong flu. […] The 21 March 2010 worldwide update, by the U.N.’s World Health Organization (WHO), states that „213 countries and overseas territories/communities have reported laboratory confirmed cases of pandemic influenza H1N1 2009, including at least 16,931 deaths.” […] The research team of Andrew Miller showed pregnant patients are at increased risk. It has been suggested that pregnant women and certain populations such as native North Americans have a greater likelihood of developing a T helper type 2 response to H1N1 influenza which may be responsible for the systemic inflammatory response syndrome that causes pulmonary edema and death.

• #25

  https://link.springer.com/article/10.1007/s00284-020-02213-x

  Influenza is a highly contagious respiratory infection caused by the circulating Swine flu virus. According to the World Health Organization (WHO), the unique blending strain of influenza A H1N1 2009 (Swine Flu) is a pandemic affecting several geographical regions, including India. […] Several studies in children have indicated that the immunization program decreased the occurrence of influenza, emphasizing the significance of communities impacted by global immunization programs. […] The highest number of hospitalizations was seen among children under the age of five. […] A 2009 study of H1N1 showed that the incidence rate of contact with children is very important for the transmission of the virus in children. […] Data from global surveillance and notification systems show a higher risk of H1N1 infection in children under two years of age, individuals with underlying medical/clinical conditions and morbidly obese people.

• #26

  https://link.springer.com/article/10.1007/s00284-020-02213-x

  The purpose of this review is to provide an overview of the burden of influenza in children worldwide, with a special focus on the 2009 H1N1 novel strain. […] It has been observed that children are highly susceptible to both seasonal and pandemic influenza. […] In terms of severity and burden of disease, the 2009 H1N1 had a significant impact on the pediatric population. […] Statistics from three influenza pandemics (Hong Kong flu, Asian flu and Spanish flu) reported the highest rates of disease in school-going children, which was also the main source of infection spread among adults. […] The decreased frequency of influenza transmission was also reported during school closure periods compared to open-time schools, indicating the crucial role of school children in the spread of influenza.

• #27 Frontiers | Influenza A Virus in Swine: Epidemiology, Challenges and Vaccination Strategies

  https://www.frontiersin.org/journals/veterinary-science/articles/10.3389/fvets.2020.00647/full

  The most effective strategy to control and prevent IAV-S infection is vaccination. […] The goal of those vaccines is to induce serum neutralizing antibodies that target the viral HA. […] In North America, vaccination against IAV-S is used more than in the EU with ~70% of the pig population being vaccinated. […] In Europe, WIV vaccines are generally administered only to sows, yet only 10–20% of the sow population is vaccinated. […] Inactivated vaccines are the traditional method to control IAV-S. Most current IAV-S vaccines contain whole inactivated viruses (WIV) with adjuvant for intramuscular injection and are either used in sows to protect them during gestation and their piglets during the suckling period or in growing pigs to decrease clinical disease. […] The introduction of specific lineages derived from human seasonal viruses such as H1N1 subtypes from 1977 and 1995 and H3N2 subtypes from 1968 and 2003 were detected in addition to H1N1pdm09.

• #28 Swine Flu (H1N!): Pandemic, Vaccine, Causes, Symptoms, Treatment & Contagious

  https://www.medicinenet.com/swine_flu/article.htm

  In uncomplicated infections, swine flu typically begins to resolve after three to seven days, but the malaise and cough can persist for two weeks or more in some patients. […] The cause of the 2009 swine flu was an influenza A virus type designated as H1N1. […] Many researchers now consider that two main series of events can lead to swine flu (and also avian or bird flu) becoming a major cause of influenza illness in humans. […] The main swine flu viruses in pigs in recent years are swine triple reassortant (tr; it means a viral strain with genes from three different organisms) H1N1, trH3N2, and trH1N2. […] The CDC recommends for the 2018-2019 flu season that everyone 6 months old and older should get a flu shot to prevent or reduce the chance of getting the flu. […] The swine flu outbreak in Mexico fit this definition. A pandemic is an epidemic that becomes so widespread that it affects a region, continent, or the world. […] On June 11, 2009, WHO officials determined that H1N1 2009 influenza the swine flu reached WHO level 6 criteria (person-to-person transmission in two separate WHO-determined world regions) and declared a swine flu pandemic, the first flu pandemic in 41 years.

• #29 Epidemiology H1N1 Influenza (Swine Flu) | PPT

  https://www.slideshare.net/onlyprabesh/epidemiology-h1n1-influenza-swine-flu

  Epidemiological Determinants 11 Causative agent: Pandemic H1N1 (2009) Influenza A virus Host Factors Occurs in every age-group. Population does not have immunity to virus Complications higher in people with underlying diseases such as asthma, cardiac diseases, renal diseases and in pregnancy. Obesity has also found to predispose to severe disease. […] Mode of Transmission 13 Through droplets from coughing or sneezing, and Through direct or indirect contact with the respiratory secretions of an infected person Food is not yet known to be a vehicle for the transmission The secondary attack rate in households:18% to 30%. […] Clinical Features 15 Ranging from mild self-limiting upper respiratory illness to lower respiratory infection including ARDS, cardiac involvement, neurological involvement, multiorgan failure, septicemia and death. Common features: mild respiratory illness with fever, cough, sore throat, dyspnea, rhinorrhea, myalgias, chills, headache and fatigue. Diarrhea and vomiting are more commonly seen than with seasonal flu. Reported complications: myocarditis, pericarditis, encephalitis, seizures, myositis, multiorgan failure and toxic shock syndrome.

• #30 H1N1 flu (swine flu) – Symptoms and causes – Mayo Clinic

  https://www.mayoclinic.org/diseases-conditions/swine-flu/symptoms-causes/syc-20378103

  The H1N1 flu, sometimes called swine flu, is a type of influenza A virus. […] During the 2009-10 flu season, a new H1N1 virus began causing illness in humans. […] The World Health Organization (WHO) declared the H1N1 flu to be a pandemic in 2009. […] But the H1N1 flu strain from the pandemic became one of the strains that cause seasonal flu. […] Influenza viruses such as H1N1 infect the cells that line your nose, throat and lungs. […] People with the virus are likely able to spread the virus from about a day before symptoms appear until about four days after they start. […] Factors that may increase your risk of developing H1N1 or other influenza viruses or their complications include: […] The Centers for Disease Control and Prevention (CDC) recommends annual flu vaccination for everyone age 6 months or older. […] The H1N1 virus is included in the seasonal flu vaccine. […] Flu vaccination is especially important because the flu and coronavirus disease 2019 (COVID-19) cause similar symptoms. […] Vaccination also helps lower the number of people with severe flu and complications.

• #31 Types of Influenza Viruses | Influenza (Flu) | CDC

  https://www.cdc.gov/flu/about/viruses-types.html

  Influenza A viruses are the only influenza viruses known to cause flu pandemics (i.e., global epidemics of flu disease). […] Currently circulating influenza A(H1N1) viruses are related to the pandemic 2009 H1N1 virus that emerged in the spring of 2009 and caused a flu pandemic (CDC 2009 H1N1 Flu website). […] Seasonal flu vaccines are formulated to protect against influenza viruses known to cause epidemics, including: one influenza A(H1N1) virus, one influenza A(H3N2) virus, and one influenza B/Victoria lineage virus.

• #32 Influenza A virus subtype H1N1 – Wikipedia

  https://en.wikipedia.org/wiki/Influenza_A_virus_subtype_H1N1

  Influenza A virus subtype H1N1 (A/H1N1) is a subtype of influenza A virus (IAV). Some human-adapted strains of H1N1 are endemic in humans and are one cause of seasonal influenza (flu). Other strains of H1N1 are endemic in pigs (swine influenza) and in birds (avian influenza). Subtypes of IAV are defined by the combination of the antigenic H and N proteins in the viral envelope; for example, „H1N1” designates an IAV subtype that has a type-1 hemagglutinin (H) protein and a type-1 neuraminidase (N) protein. […] Major outbreaks of H1N1 strains in humans include the 1918 Spanish flu pandemic, the 1977 Russian flu pandemic and the 2009 swine flu pandemic, all of which were caused by strains of A(H1N1) virus which are believed to have undergone genetic reassortment. […] Each year, three influenza strains are chosen for inclusion in the forthcoming year’s seasonal flu vaccination by the Global Influenza Surveillance and Response System of the World Health Organization (WHO). Since 1999, every annual formulation has included one strain of A/H1N1 as well as two other influenza strains – together representing strains thought most likely to cause significant human suffering in the coming season.

• #33 Epidemiology H1N1 Influenza (Swine Flu) | PPT

  https://www.slideshare.net/onlyprabesh/epidemiology-h1n1-influenza-swine-flu

  Prevention and Control Measures 18 Non-Pharmacological Interventions Personal protective measures Shielding ones mouth and nose while coughing or sneezing, Frequently washing ones hands with soap Isolation and social distancing Home quarantine School closure and cancellation of mass gathering Pharmacological Interventions Chemoprophylaxis If the likelihood of complications is high, oseltamivir or zanamivir may be used as post-exposure chemoprophylaxis for affected individuals, especially healthcare workers. […] Pharmacological Interventions Vaccination Vaccine against the H1N1 virus is presently available in a few countries. Commercial production is about to commence. The first priority of all countries should be to immunize their healthcare workers The next priority should be pregnant women. Inactivated non- adjuvant vaccines similar to most seasonal influenza vaccines are considered the preferred option.

• #34

  https://www.who.int/news/item/30-03-2024-2023–outbreaks-of-swine-influenza

  The following outbreaks, which occurred last year, illustrate the reality of zoonotic influenza, the fact that all ages can be vulnerable, that those with and without comorbidities can be at risk, and that various exposures can lead to swine influenza infection. […] The diversity of zoonotic influenza viruses that caused human infections in 2023 is alarming and infections of some types of zoonotic influenza viruses caused severe disease with a high mortality rate. […] WHO will continue to strengthen surveillance, jointly with its partners, in both animal and human populations, thoroughly investigate every zoonotic infection, build up pandemic preparedness planning, and get better readiness for the next influenza pandemic. […] On 7 June 2023, WHO was notified of a fatal laboratory-confirmed human case of infection with a swine-origin influenza A(H1N1) variant (v) virus in the inner state of Paran.

• #35

  https://www.who.int/news/item/30-03-2024-2023–outbreaks-of-swine-influenza

  On 4 August 2023, WHO was notified of a human infection with a novel influenza A(H1N2) variant virus identified in the State of Michigan. […] On 2 September 2023, WHO was notified of a laboratory-confirmed human case of infection with a swine-origin influenza A(H1N1) variant (v) virus in the province of North Brabant, Netherlands. […] On 25 November 2023, WHO was notified of a human case of swine-origin influenza A(H1N2) virus infection.

• #36 GISAID – New swine flu enters the watchlist

  https://gisaid.org/resources/statements-clarifications/new-swine-flu-enters-the-watchlist/

  Virus surveillance in animals is an important aspect of pandemic preparedness to know what is out there and could cause zoonotic infections (jumps from animals to humans) or even represent pandemic threats. […] Researchers have concluded a surveillance study in pigs and identified a new reassortant H1N1 swine flu that shows the minimal characteristics for a virus with pandemic potential. […] There is no evidence that people are infected beyond sporadic cases in the pig industry. But it is very important to have this virus on the radar for pandemic preparedness. […] The G4 strain that has become dominant since 2016 has acquired the M segment from pdm09 viruses and thus has the same target for which common flu A primers have been designed. […] The virus would easily be identified as influenza A virus but further steps are needed to characterize it, based on HA, NA and other segments.

• #37 GISAID – New swine flu enters the watchlist

  https://gisaid.org/resources/statements-clarifications/new-swine-flu-enters-the-watchlist/

  There is evidence that it can infect humans based on swine worker serology and occasional zoonoses caused by viruses with a related HA. […] The virus was found to be transmissible between ferrets, which is taken as a warning for possible transmissibility between humans. […] Given that most of the world population would not have specific antibodies against HA of the virus (the HA surface protein is only 78.6% identical to the closest recent human virus which is H1N1pdm09), population immunity is likely to be low. […] Influenza viruses have been and always will be a problem to watch out for. Reassortment of viruses at the animal-human interface continues to be a serious problem. […] This G4 virus is one of several swine viruses with zoonotic potential in the world. […] It is currently impossible to predict exactly which one will cause the next pandemic and therefore we need to respond to each identified threat and be prepared for any emergency response that might arise.

• #38 Swine InfluenzaLockBack to top

  https://www.aphis.usda.gov/livestock-poultry-disease/swine/influenza-a-virus

  Swine influenza is widespread in North and South America, Asia, and Europe. The most common strains found in the United States are H1N1, H1N2, and H3N2. […] APHIS works with animal health and public health officials and the swine industry to carry out a robust and coordinated Influenza A Swine Surveillance Program. Swine are susceptible to infection by human, avian, and swine influenza viruses, which can lead to novel reassortments. The surveillance program aims to identify influenza viruses circulating in swine, proactively identify reassortment viruses that could impact public health, and gain knowledge to contribute to improved animal health diagnostics and vaccines.

• #39 Influenza pandemic (H1N1) of 2009 | Causes, Symptoms & Treatment | Britannica

  https://www.britannica.com/event/influenza-pandemic-H1N1-of-2009

  The new H1N1 virus emerged in the United States in April 2009, in Texas, New York, California, and several other places. […] On April 25, 2009, the director general of the World Health Organization (WHO), Margaret Chan, declared the outbreak a public health emergency of international concern. […] This evidence prompted Chan and WHO on April 29 to declare a level 5 pandemic alert for the H1N1 outbreak. […] To relieve tensions and to avoid further confusion, WHO officially renamed the outbreak influenza A (H1N1).

• #40 H1N1 Influenza (Swine Flu) Workup: Laboratory Studies

  https://emedicine.medscape.com/article/1807048-workup

  Outbreaks of H1N1 influenza (swine flu) are common in pigs year-round. Historically, when humans have become infected, it is a result of close contact with infected pigs (but not consumption of pork). In major outbreaks, human-to-human transmission occurs. […] In the 2009-2011 outbreak, the WHO raised its pandemic alert level for H1N1 influenza to phase 6, indicating that a global pandemic was identified. […] In the 2009-2010 outbreak in the United States, preliminary testing showed that, in all cases, the viruses had the same genetic pattern. The virus is being described as a new subtype of influenza A/H1N1 not previously detected in pigs or humans. […] Clinicians should consider the possibility of H1N1 influenza virus infections in patients who present with febrile respiratory illness.

• #41 H1N1 Influenza (Swine Flu) Workup: Laboratory Studies

  https://emedicine.medscape.com/article/1807048-workup

  Laboratories should send all influenza A specimens that they are unable to subtype to the Viral Surveillance and Diagnostic Branch of the CDC’s Influenza Division as soon as possible for further diagnostic testing. […] Internationally, scientists have been collaborating on genetic analysis of current animal and human influenza viruses. These researchers have created a human/swine A/H1N1 influenza wiki to facilitate rapid dissemination of the results of this work. The collaboration is producing insights on the origin of the H1N1 virus and should enable scientists to track its evolution as the outbreak spreads around the world.

• #42 Origins and evolutionary genomics of the 2009 swine-origin H1N1 influenza A epidemic | Nature

  https://www.nature.com/articles/nature08182

  In March and early April 2009, a new swine-origin influenza A (H1N1) virus (S-OIV) emerged in Mexico and the United States. During the first few weeks of surveillance, the virus spread worldwide to 30 countries (as of May 11) by human-to-human transmission, causing the World Health Organization to raise its pandemic alert to level 5 of 6. This virus has the potential to develop into the first influenza pandemic of the twenty-first century. […] Our results highlight the need for systematic surveillance of influenza in swine, and provide evidence that the mixing of new genetic elements in swine can result in the emergence of viruses with pandemic potential in humans. […] The emergence of S-OIV provides further evidence of the role of domestic pigs in the ecosystem of influenza A. […] Yet despite widespread influenza surveillance in humans, the lack of systematic swine surveillance allowed for the undetected persistence and evolution of this potentially pandemic strain for many years.

• #43 Researchers Discover the 2009 Swine Flu Pandemic Originated in Mexico | Mount Sinai – New York

  https://www.mountsinai.org/about/newsroom/2016/researchers-discover-the-2009-swine-flu-pandemic-originated-in-mexico

  The 2009 swine H1N1 flu pandemic — responsible for more than 17,000 deaths worldwide — originated in pigs from a very small region in central Mexico, a research team headed by investigators at the Icahn School of Medicine at Mount Sinai is reporting. […] Researchers used state-of-the-art genetic analysis to identify the precise location and the main molecular transformations that allowed a pig influenza virus to jump into humans. […] Knowing where and how an animal influenza virus infects humans and spreads all over the world helps us understand how we can reduce risk of these pandemics, says the study’s senior author, Adolfo García-Sastre, PhD, Director of the Global Health and Emerging Pathogens Institute, Irene and Dr. Arthur M. Fishberg Chair and Professor of Medicine (Infectious Diseases), and Professor of Microbiology at the Icahn School of Medicine at Mount Sinai.

• #44 Researchers Discover the 2009 Swine Flu Pandemic Originated in Mexico | Mount Sinai – New York

  https://www.mountsinai.org/about/newsroom/2016/researchers-discover-the-2009-swine-flu-pandemic-originated-in-mexico

  Worldwide surveillance of active flu in pigs is crucial because swine are a common global commodity, Dr. Garcia-Sastre says. “We need to monitor the viruses that are circulating, and try to stop mixing influenza strains from different geographic locations,” he says. “This study also shows that you cannot ignore small geographic areas with pig farms —places in which the 2009 pandemic originated and which the next, perhaps more severe global flu, may come from.”

• #45 What We Can Learn from the H1N1 Flu Pandemic | ThinkSet | BRG

  https://www.thinkbrg.com/thinkset/ts-what-we-can-learn-from-h1n1-flu-pandemic/

  As the world grapples with COVID-19, we can draw lessons from steps taken to combat the H1N1 flu pandemic […] The specific behaviors and treatments of H1N1 represented uncharted territory, and to conquer it, the world needed to first understand how many people were infected, how quickly the virus spread and whether countermeasures like social distancing and closing schools were effective. […] Survey respondents provided critical data that helped show that the disease appeared to peak in late April 2009 and that incidences of infection dropped noticeably when schools were on vacation or closed. This helped track the effectiveness of the countermeasures being used to slow the virus’s spread. […] The recently passed CARES Act includes a provision that sets aside $500 million for the CDC to develop a public health surveillance and data collection system for coronavirus within 30 days of enactment of this Act. Time will tell what form that takes and how much that surveillance system owes to the pioneering experiments in 2009 surrounding the H1N1 crisis.

• #46 Epidemiology H1N1 Influenza (Swine Flu) | PPT

  https://www.slideshare.net/onlyprabesh/epidemiology-h1n1-influenza-swine-flu

  National Response 20 National Influenza Surveillance Network (10 sentinel sites) Molecular diagnostic assay based influenza surveillance started in 2009 with the introduction of Real-Time PCR (RT- PCR) at National Public Health Laboratory (NPHL) Community spread of Pandemic Influenza A/H1N1 2009 was established in Kathmandu valley on 15th October, 2009. NPHL designated as National Influenza Centre (NIC) on 19th April, 2010 Influenza Pandemic Preparedness and Response Project (IPPRP) implemented by PAHS under grants from CDC.

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