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Influenza A

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The biosynthesis of proBNP and its derivatives.[1]

Contents

General Information

The theme of SensUs 2021 is acute respiratory viruses. The current Covid-19 pandemic has made it apparent that large virus outbreaks can cause immense harm to human health and can disrupt society as a whole. The most common respiratory virus is influenza A. Therefore, the influenza virus serves as an interesting biomarker for this year’s Competition.

The influenza A virus is known to cause influenza in birds and some mammals, like humans. Different subtypes of the influenza A virus have been isolated from wild birds. Some subtypes of the influenza A virus can cause severe symptoms both in domestic poultry and (rarely) in humans and can even lead to death. Occasionally, viruses can be transmitted from wild birds to domestic animals, like chickens or pigs. This may give rise to human influenza. Influenza A viruses are negative-sense, single-stranded RNA viruses. Different subtypes of influenza A exist, these are characterized by proteins on the outermost membrane of the virus, called hemagglutinin (H or HA) and neuraminidase (N or NA). H and N are the antigens of the virus, and play an important role in the interaction between the host’s immunological response and the virus. Recently, researchers have reported the discovery of an antibody which is generally effective against all types of the influenza A virus. The subtype which will be used in SensUs 2021 is H1N1. Historically, H1N1 has been responsible for most deaths due to influenza. It is a popular influenza strain for research purposes [link, link, link] . Due to its popularity among researchers, antigens and antibodies are commercially available, making H1N1 suitable as a target for the SensUs competition. Influenza A vaccines for humans have been developed. New versions of the vaccines are developed twice per year for use all over the world, which is necessary due to rapid mutations of the influenza virus. Every year during flu season, a large part of the population is vaccinated in order to protect individuals against the virus. However, due to unforeseen mutations of the virus, it might be possible that in a certain year a vaccine will prove ineffective. In that case large portions of the population would be at risk and a pandemic could occur. The probability of a major influenza A pandemic is estimated to be around 0.5-1% each year.

History of influenza (A)

A lack of data up until 1500 AC complicates the research on influenza before that period.[206] Possibly the first influenza pandemic occurred around 6000 BC in China. The symptoms of human influenza seem to have been clearly described by Hippocrates, roughly 2,400 years ago[207][208]. Although the virus seems to have caused epidemics throughout human history, historical data on influenza is difficult to interpret, due to the fact that symptoms of influenza are similar to those found in other respiratory diseases, like RSV (respiratory syncytial virus). The most infamous and lethal outbreak was the 1918 flu pandemic (Spanish flu) (type A influenza, H1N1 subtype), which lasted into 1920. The number of deaths is unknown, but estimates range from 17 to 100 million people. This pandemic has been described as "the greatest medical holocaust in history" and may have killed as many people as the plague (Black Death). This huge death toll was caused by an extremely high infection rate of up to 50% and the severity of the symptoms, suspected to be caused by cytokine storms in which the innate immune system causes an uncontrolled and excessive release of pro-inflammatory signaling molecules called cytokines. One of the most recent outbreaks of influenza was the 2009 Swine Flu. Similar to the Spanish Flu, it was also of the subtype H1N1. The death toll of the 2009 pandemic is estimated to be around 150,000 to 575,000.

Structure of the influenza virus

The virus particle (virion) is 80–120 nanometers in diameter. The virion shape can be spherical, elliptical, or even filamentous with a length of tens of micrometers. The virion is made up of a viral envelope containing two main types of proteins, wrapped around a central core. The two large proteins found on the outside of viral particles are hemagglutinin (HA) and neuraminidase (NA). HA is a protein that mediates binding of the virion to target cells and entry of the viral genome into the target cell, and therefore plays an important role in infecting healthy cells. NA is involved in releasing the progeny viruses once a cell has been infected and has started producing the virus itself. These two proteins are a target of interest for antiviral drugs. Furthermore, they are also the antigen proteins to which a host antibodies can bind and trigger an immune response. Influenza type A viruses are categorized into different subtypes, or strains, based on which type of these two proteins is present on the surface of the virion. Currently, there are 16 subtypes of HA and 9 subtypes of NA known to exist. The most prevalent form of the different subtypes is H1N1. Single hemagglutinin-neuraminidase proteins, in which both HA and NA are found in a single protein, also exist. However, these will not be used in SensUs 2021.

Mechanism of Infection

The involvement of the hemagglutinin and neuraminidase proteins in the infection of H1N1 is essential for the virus reproduction, and a more specific mechanism is discussed below. The hemagglutinin protein (HA) has the role of searching for the sialic acid receptors in respiratory-lining cell membranes. (figure _). Upon binding of this protein and the receptor, fusion of the virus and the cell membrane is facilitated with the help of glycan proteins. The virus then enters the cell where it sheds its shell and approaches the cell’s nucleus. Using the host replication mechanisms, the virus makes copies of itself. At this step of the infection process, important viral proteins are synthesized. These newly replicated viral elements subsequently attempt to leave through the cell membrane and infect other cells. To inhibit the exit of the viral components, sialic acid receptors on the cell membrane attempt to bind the HA glycoproteins. This is where viral evolution/mutability can play a role in the expansion of the capabilities of the virus. The neuraminidase glycoprotein (N) has the role of cleaving the sialic acid receptors, allowing the exit of the viral components which then go in search of a new host. After infection is complete, the H1N1 virus triggers cell apoptosis, leading to the death of the cell and spread of the virions. pictures

Medical Application

Optimal dose and effects are achieved with upper limit of 60 mg/kg/day. If the desired effects are not achieved (in other words, the seizures are not gone or the The influenza virus spreads when people with the flu cough, sneeze or talk. Infected people transfer tiny droplets to people close to them and infect them by the handover of droplets (Influenza (Flu) 2019). During an outbreak, it is important to be able to control and prevent the virus from spreading further, for example, by implementing control measures. Those control measures can be determined based on the reproduction number. The reproduction number is defined as: “the expected number of secondary cases produced by a single infection in a completely susceptible population”(https://web.stanford.edu/~jhj1/teachingdocs/Jones-on-R0.pdf). A clear overview of the number of infected people is needed to calculate the reproduction number. For disease control, it is crucial to know the infection rate in a specific region. The results may influence critical decisions such as whether to perform other diagnostic testing or to implement infection prevention and control measures for influenza (Overview of Influenza testing methods 2020). Furthermore, manpower can be in short supply during a pandemic and the speed at which someone can be tested and receive the result is of vital importance. Biosensors that will be developed in SensUs 2021 are envisioned to be used outside the hospital in a point-of-care (POC) setting. Inside the hospital there is not a big advantage, as there are already very specific and accurate tests available for that setting (Diagnosis, 2020). Important applications are fast testing at the GP and at home. Therefore the test should be easy to use. The biosensors will be designed to enable a fast yes/no answer, based on measuring the concentration of viral particles in the sample. The biosensors will not distinguish between different virus subtypes, as the subtype causing the pandemic is assumed to be known.

State of the Art

Still paste some tables

Safety

When working with the influenza virus, influenza infection in humans can occur following a laboratory accident. For safety reasons, inactivated virus particles will be used in SensUs 2021, as a substitute for infectious influenza virus particles.

Lab Protocols

The use of safety equipment combined with good practices is fundamental to laboratory safety and in helping to reduce the risks involved in dealing with biosafety hazards. According to Article 4.84 of the Working Conditions Decree, the inactivated virus particles can be classified as category 1 of the biological agents, as they are unlikely to cause disease in humans. Therefore, only the biosafety guidelines as defined in the ML-1 (minimum containment level) have to be followed. It is stipulated in the guidelines that general laboratory protocols such as the usage of barrier protection (lab coats, gloves and face protection) when handling the samples are to be followed. The protection barriers are not always necessary from a microbiological perspective. However, it is compulsory when handling disinfectants or solvents.

References

  1. Cardiac biomarker testing in the clinical laboratory: Where do we stand? General overview of the methodology with special emphasis on natriuretic peptides, Aldo Clerico, Claudio Passino, Maria Franzini, Michele Emdin, June 2014, Clinica Chimica Acta, http://dx.doi.org/10.1016/j.cca.2014.06.003