Influenza Basics
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Approximately 9% of the world’s population is affected annually, with up to 1 billion infections, 3 to 5 million severe cases, and 300,000 to 500,000 deaths each year.

Terminology

Influenza viruses are named after the Latin word "Influentia", meaning “influence”. There are four types of influenza viruses: A, B, C and D. During "flu season" several influenza A and B viruses are spreading. Only influenza A viruses are known to cause pandemics, health emergencies on a global scale. Influenza viruses possess three membrane proteins, the hemagglutinin (HA), the neuraminidase (NA), and the matrix protein M2. The membrane is the surface of the virus and is the part visible to the immune system. The 16 major antigenic variants of HA and 9 of NA are used for classification. The currently most relevant influenza virus subtype has variant 5 of HA and variant 1 of NA, therefore the subtype is named H5N1. This classification is biologically relevant because antibodies generally don't cross-react to different subtypes. This is why scientists try to create antibodies with a broader range of subtypes and the seasonal influenza vaccine is a mix of 3 or 4 different vaccines. The CDC provides more details on the terminology. This overview shows how HA is used for classification and the recent variants of H5N1, H5N6, and H5N8 are closely related.

Some are categorised as highly pathogenic, and others as low pathogenic. This is determined through the intravenous pathogenicity index test, a laboratory technique used to assess how well avian influenza viruses cause disease in poultry.

Mutations

Influenza viruses have segmented RNA genomes, consisting of eight segments. The eight segments are PB2, PB1, PA, NP, HA, NA, M, and NS. Influenza viruses tend to mutate rapidly, changing single nucleotides. This is called "genetic drift". But their true superpower is that they can swap entire segments, resulting in sudden and drastic changes. This is called "genetic shift". A lethal H5N1 virus could one day swap segments with one of the many influenza viruses well adopted to spreading between humans. This could suddenly start a very deadly outbreak, or even a pandemic. One example of reassortment is the virus infecting cows.

>> Mutations

According to our GenoFlu analysis, the B3.7 genotype represents a 4+4 reassortant strain, with the HA, NA, PA, and MP genes originating from the H5N1 virus strain in 2020, while the remaining segments (PB2, PB1, NP, and NS) are closely related to LPAI viruses.
The sample was successfully sequenced, and phylogenetic analysis of the haemagglutinin (HA) gene showed the virus to be H5 clade 2.3.2.1c, similar to the viruses circulating in Cambodia and Southeast Asia since 2013-2014. However, its internal genes belong to H5 clade 2.3.4.4b viruses. This novel reassortant influenza A(H5N1) virus has been detected in human cases reported in Cambodia since late 2023.

History

The first influenza pandemic that is scientific consent was in 1580, followed by 1729, 1781, 1830, 1898, H1N1 in 1918, H2N2 in 1957, H3N2 in 1968, and H1N1 in 2009. According to this source this resulted in 40-50 million deaths in 1918-1920, 1-2 million deaths in 1957-1958, 0.5 million to 2 million deaths in 1968-1970 and around 0.5 million deaths in 2009. The 1830 pandemic was comparable with the 1918 pandemic in terms of severity (C. W. Potter, A history of influenza), although population growth and rapid societal development make those comparisons difficult. While a pandemic of similar severity would theoretically result in around 250 million deaths today, this raises for example the question to what extend people in 1918-1920 died from co-infections that would be more easily treatable today. The 2009 H1N1 swine flu pandemic had a similar impact as the yearly influenza season, with several hundred thousand deaths and around 1 billion infections worldwide.
It is tempting to think that modern influenza pandemics may have to look similar to the 2009 H1N1 swine flu pandemic. But history clearly indicates that influenza viruses can become very lethal, regardless of old age, aftereffects of war like malnutrition, co-infections or any other explanations.
The extremely high H5N1 case fatality rate may actually be in the double-digits and the nightmare may become reality. The history of a potential bird flu pandemic has already begun with Covid-19, the politicization of public health measures and general pandemic fatigue.
If we take this history into account, it becomes clear that the medical consequences may be overshadowed by even worse disruptions of our complex, interconnected society. Reading "The Story of Influenza" is highly recommended to understand the social context of a severe pandemic.

An estimated one third of the world's population (or ≈500 million persons) were infected and had clinically apparent illnesses during the 1918–1919 influenza pandemic. The disease was exceptionally severe. Case-fatality rates were >2.5%, compared to <0.1% in other influenza pandemics. Total deaths were estimated at ≈50 million and were arguably as high as 100 million.
The world population in 1918 was only 28 percent of today's population. Adjusting for population, a comparable toll today would be 175 to 350 million. By comparison, at this writing AIDS has killed approximately 24 million, and an estimated 40 million more people are infected with the virus.
Strikingly, persons less than 65 years old accounted for more than 99 percent of all excess influenza-related deaths in 1918–1919 (...).
But perhaps most disturbing and most relevant for today is the fact that a significant minority—and in some subgroups of the population a majority—of deaths came directly from the virus, not from secondary bacterial pneumonias. In 1918, pathologists were intimately familiar with the condition of lungs of victims of bacterial pneumonia at autopsy. But the viral pneumonias caused by the influenza pandemic were so violent that many investigators said the only lungs they had seen that resembled them were from victims of poison gas.
The 1918 virus, especially in its second wave, was not only virulent and lethal, but extraordinarily violent. It created a range of symptoms rarely seen with the disease. After H5N1 first appeared in 1997, pathologists reported some findings “not previously described with influenza” (...). In fact, investigators in 1918 described every pathological change seen with H5N1 and more (...). Symptoms in 1918 were so unusual that initially influenza was misdiagnosed as dengue, cholera, or typhoid. One observer wrote, “One of the most striking of the complications was hemorrhage from mucous membranes, especially from the nose, stomach, and intestine. Bleeding from the ears and petechial hemorrhages in the skin also occurred” (...).
While both 1918 reassortant viruses also were highly pathogenic, the H5N1 virus was exceptional for the extent of tissue damage, cytokinemia, and interference with immune regulatory mechanisms, which may help explain the extreme virulence of HPAI viruses in humans.
Virtually every expert on influenza believes another pandemic is nearly inevitable, that it will kill millions of people, and that it could kill tens of millions—and a virus like 1918, or H5N1, might kill a hundred million or more—and that it could cause economic and social disruption on a massive scale. This disruption itself could kill as well.

Questions and Answers

What is happening?
The avian influenza virus H5N1 has mutated and is spreading worldwide, killing millions of animals, mostly birds. This is called a panzootic. H5N1 was first discovered in Hong Kong in 1996. The new variant H5N1 clade 2.3.4.4b was discovered in Europe in 2020 and has since then spread around the world. H5N1 has already reached all continents except Australia and is spreading throughout all seasons. This is unprecedented.

What is the risk?
The risk is adaptation to mammals, leading to sustained mammal-to-mammal transmission and ultimately sustained human-to-human transmission, causing a pandemic. This pandemic bird flu would likely be as transmissible as other influenza viruses, but very lethal with a case fatality rate in the double-digits.

What needs to happen for the virus to be cause a pandemic?
Birds and mammals have different receptors in their airways. But the difference is gradual and some animals like minks have a more even distribution of both receptors in the same part of their airways. The virus needs to change its' preference from birds to mammals. For this some mutations are necessary. Those mutations could occur in farms with a lot of mammals in a small space, especially fur farms or hog farms. The virus could also evolve in cats, which often come into contact with both birds and humans. There are many interactions between mammals and infected birds and each of them could cause a pandemic.

Has there been human-to-human transmission?
Probably yes, but transmission was not even close to sustained. Genetic analysis and serologic tests both confirm a low transmission potential. Furthermore, there are many uncertainties regarding human-to-human transmission. There are various cases of likely human-to-human transmission.

Has there been mammal-to-mammal transmission?
Probably yes, very likely between minks on fur farms. Mammal-to-mammal transmission between seals and sea lions is also very likely, although contamination with birds feces is also relevant. Of course mammal-to-mammal transmission happened in laboratory experiments. A special case is bird flu in cows, because transmission seems to be caused by contaminated milk and milking equipment.

Does the seasonal influenza vaccination prevent bird flu infections?

"Seasonal flu vaccination will not prevent infection with bird flu viruses but can reduce the risk of getting sick with human and bird flu viruses at the same time."


Are there antiviral drugs to treat bird flu?
Yes, there are antiviral drugs, but they could be better.

Are there vaccines to prevent bird flu?
Yes, there are vaccines, but it is uncertain how well they would work.

Are there stockpiles of antiviral drugs and vaccines?
Yes. The USA has stockpiled around 200 million doses of antiviral drugs and vaccines for around 20 million people. The strategy is to protect healthcare workers and critical infrastructure first. There are various agreements and stand-by production capabilities. CSL would for example deliver 150 million doses within 6 months. The situation in developing countries would be a lot worse.

What medical countermeasures are in development?
Long-lasting antibodies may improve both treatment and prevention. mRNA vaccines will improve efficacy and production process of vaccines.

What can be done to prevent a bird flu infection?
With less than 1.000 documented H5N1 cases, the personal risk for an average person is currently minimal. Pets are at risk from contact with wild birds. A pandemic bird flu would probably be as transmissible as the seasonal influenza, far less than Covid-19. Buying masks would drastically reduce the infection risk in case of a pandemic.

What other influenza viruses are considered especially dangerous?
Double-digit case fatality rates also occur with H5N6 and H7N9. The risk assessment tool IRAT of the CDC puts an emphasis on existing adaptation to humans. This explains the high ranking of seasonal influenza components H1N1 and H3N2. H7N9 is ranked third with about twice as many documented human infections as H5N1 and a case fatality rate of 39%. A H3N8 virus with concerning mutations has recently been documented.