December 22, 2024

Could the vaccine be responsible for the new variants? Also, gain an understanding of the Paramyxovirus Family

In recent times, there has been much discussion and debate surrounding the role of vaccines in the creation of new variants of viruses. Many people are questioning whether the very thing meant to protect us from illness is actually contributing to the evolution of more dangerous strains. So, are vaccines really creating the variants? 

Vaccines have been a topic of debate for years, with concerns ranging from their efficacy to potential side effects. One question that often arises is whether vaccines can cause types of paramyxoviruses, a group of viruses that includes measles, mumps, and respiratory syncytial virus. In this article, we will explore the relationship between vaccines and paramyxoviruses and provide insight into this important issue.

Paramyxoviridae (from Greek para- “by the side of” and myxa “mucus”) is a family of negative-strand RNA viruses in the order Mononegavirales. Vertebrates serve as natural hosts. Diseases associated with this family include measles, mumps, and respiratory tract infections. The family has four subfamilies, 17 genera, three of which are unassigned to a subfamily, and 78 species.

What are Paramyxoviruses?

Paramyxoviruses are a family of viruses that can cause a range of illnesses in humans, including respiratory infections, measles, mumps, and more. According to WHO, these viruses are highly contagious and can spread through respiratory droplets, making them a public health concern. Symptoms of paramyxovirus infections can vary, but they often include fever, cough, and congestion.

What Are the Types of Paramyxoviruses?

In the world of virology, there are various families of viruses that pose a threat to human health. One such family is the Paramyxoviridae family, which includes a number of viruses that can cause respiratory and neurological diseases in humans and animals. Understanding the different types of paramyxoviruses is crucial in order to effectively combat and prevent their spread.

Types of Paramyxoviruses:

  1. Measles Virus: Perhaps one of the most well-known paramyxoviruses, the measles virus is highly contagious and can lead to serious complications, especially in young children. Symptoms of measles include fever, rash, cough, and runny nose.
  2. Mumps Virus: The mumps virus is another member of the paramyxovirus family that causes swelling of the salivary glands. In severe cases, mumps can lead to complications such as meningitis and deafness.
  3. Respiratory Syncytial Virus (RSV): RSV is a common cause of respiratory infections in young children and can lead to more severe symptoms in infants and elderly individuals. Symptoms of RSV include coughing, wheezing, and difficulty breathing.
  4. Parainfluenza Virus: This paramyxovirus is a common cause of respiratory infections in young children, often leading to symptoms such as croup and bronchiolitis. Parainfluenza viruses can also cause pneumonia in severe cases.
  5. Nipah Virus: Nipah virus is a zoonotic paramyxovirus that can be transmitted from animals to humans, leading to severe respiratory and neurological symptoms. Outbreaks of Nipah virus have been reported in Southeast Asia.
  6. Hendra Virus: Similar to Nipah virus, Hendra virus is also a zoonotic paramyxovirus that can be transmitted from horses to humans. Symptoms of Hendra virus infection include respiratory distress and encephalitis.
  7. Newcastle Disease Virus (NDV): This paramyxovirus primarily affects birds, leading to severe respiratory symptoms and a high mortality rate in poultry populations. Newcastle disease can have significant economic impacts on the poultry industry.

Types of Paramyxoviruses Vaccines

There are several types of vaccines used to prevent paramyxovirus infections:

  1. Live Attenuated Vaccines: Live attenuated vaccines contain a weakened form of the virus that is still able to replicate but causes only mild or no symptoms in most people. Examples of live attenuated paramyxovirus vaccines include the measles, mumps, and rubella (MMR) vaccine.
  2. Inactivated Vaccines: Inactivated vaccines contain killed virus particles that cannot replicate in the body. These vaccines are typically safe for people with weakened immune systems. The inactivated polio vaccine is an example of an inactivated paramyxovirus vaccine.
  3. Subunit Vaccines: Subunit vaccines contain only a part of the virus, such as a protein or sugar molecule, that triggers an immune response. These vaccines are often safer and produce fewer side effects than live or inactivated vaccines. The hepatitis B vaccine is an example of a subunit paramyxovirus vaccine.
  4. Viral Vector Vaccines: Viral vector vaccines use a harmless virus to deliver genetic material from the target virus into cells, triggering an immune response. This approach can provoke a strong and long-lasting immune response. Some COVID-19 vaccines, such as the Oxford-AstraZeneca vaccine, use viral vector technology.

Nobel Prize in 2008

While it is understood that viruses mutate, causing variants, French Virologist and Nobel Prize Winner Luc Montagnier contends that “it is the vaccination that is creating the variants.”

Prof. Luc Montagnier said that epidemiologists know but are “silent” about the phenomenon, known as “Antibody-Dependent Enhancement” (ADE).

Video: Vaccines are Creating the Variants and Notable young people with thromboses

Prof. Montagnier referred to the vaccine program for the coronavirus as an “unacceptable mistake”. Mass vaccinations are a “scientific error as well as a medical error,” he said. “It is an unacceptable mistake. The history books will show that, because it is the vaccination that is creating the variants,” Prof. Luc Montagnier continued.

The prominent virologist explained that “there are antibodies, created by the vaccine,” forcing the virus to “find another solution” or die. This is where the variants are created. It is the variants that “are a production and result from the vaccination.”

NIH Report:

Paramyxoviruses (some of which are also called parainfluenza viruses) cause a wide variety of diseases in animals. Many paramyxoviruses cause primarily respiratory disease, while others cause serious systemic disease. Many diseases caused by animal paramyxoviruses also have a neurological component or a reproductive disease component. Several of the most devastating diseases of animals, such as rinderpest, Newcastle disease, and canine distemper, are caused by paramyxoviruses. Some of the animal paramyxoviruses, such as the Hendra and Nipah viruses, are emerging zoonotic pathogens of major public health concern. New paramyxoviruses are being isolated on a continuing basis from a wide variety of animals.

All animal paramyxoviruses belong to the family Paramyxoviridae. The members of this virus family are enveloped and have genomes consisting of a single segment of negative-sense RNA that contains 6–10 genes encoding up to 12 proteins. Although there are many animal paramyxoviruses, only a few vaccines are currently available. In the last decade, methods of producing many animal paramyxoviruses entirely from cDNA clones (reverse genetics) have been developed. This has not only greatly improved our understanding of the molecular biology and pathogenesis of these viruses, but has also made it possible to engineer improved vaccines for them.

Another important aspect of this new technology is that vaccines can now be designed for some of the animal paramyxoviruses for which either vaccines are not currently available or the available vaccines are not satisfactory.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7149509/
https://www.bioveta.eu/en/products/veterinary-products/pmv-salmo-vac-emulsion-for-injection-for-pigeons.html
https://www.meditechuk.com/products/colombovac-paramyxo-vaccine-100d


https://www.vitakingproducts.com/product-p/vac0011.htm

The concept behind paramyxovirus vaccine vectors is to use the genetic material of two specific viruses, HPIV-3 and NDV, to create a new vector that can be used to deliver antigens and stimulate immune responses. By utilizing the genetic backbone of these viruses, researchers are able to modify them 

The modified NDV vector, carrying APMV-3, is then administered to chickens and Guinea pigs.

A study published in late 2020, long after the pandemic started and EcoHealth Alliance (EHA) faced scrutiny for funding risky animal experiments at the Wuhan Animal Lab, revealed that Fauci personally reviewed and endorsed a study co-authored by Daszak. The study detailed EHA’s expedition to Bangladesh to gather the highly-lethal Nipah virus from wild bats. In addition to editing and approving Daszak’s paper for publication, Fauci also provided funding for the research.

Scientist: Wuhan Lab Researched Lethal Nipah Virus; China Tech Firms Share Algorithms with Regime

There are three major reasons why vaccines are never 100% effective. If the vaccine was administered incorrectly, perhaps at the wrong time or with a vaccine that has been improperly handled, then it may not work. Alternatively, variations in individual animal responses will always ensure that some will not be protected. Likewise premature vaccination and subsequent failure as a result of maternal antibodies is a major cause of failure. Finally, given the careful quality control of vaccine production by major manufacturers, production of an ineffective vaccine is rare. The issue of lapsed vaccination is also considered.

Failures in vaccination

There are three major reasons why vaccines are never 100% effective. If the vaccine was administered incorrectly, perhaps at the wrong time or with a vaccine that has been improperly handled, then it may not work. Alternatively, variations in individual animal responses will always ensure that some will not be protected. Likewise premature vaccination and subsequent failure as a result of maternal antibodies is a major cause of failure. Finally, given the careful quality control of vaccine production by major manufacturers, production of an ineffective vaccine is rare. The issue of lapsed vaccination is also considered.

Ref: https://www.sciencedirect.com/science/article/abs/pii/B9780323682992000186

Adverse consequences of vaccination

The importance of adverse effects from vaccination must not be overstated. Unnecessary vaccination must be discouraged. Hypersensitivity reactions to vaccine components are real and must be guarded against. Residual virulence, although a concern tends to be more a hypothetical than a real problem. Progressive improvements in animal vaccines have significantly reduced the chances of adverse effects occurring, although some issues persist. One such example is injection-site sarcomas in cats. Another issue is the influence of animal size on the prevalence of adverse events in dogs.

The association should be distinctive and the adverse event linked specifically to the vaccine concerned. It is important to remember that an adverse event may be caused by vaccine adjuvants and components other than the major antigens. Administration of the vaccine should precede the earliest manifestations of the event or a clear exacerbation of a continuing condition.

The US Centers for Disease Control and Prevention (CDC) has classified adverse events as follows:

  • Vaccine-induced events: This would be an allergic response to a vaccine component such as egg protein.
  • Vaccine-potentiated reactions: These are events that might have occurred anyway but may have been precipitated by the vaccine. One possible example is purpura hemorrhagica in horses.
  • Programmatic error: Events that occur in response to technical errors in vaccine storage, preparation, handling, and administration.
  • Coincidental events: These are simply events that happen by chance or result from some underlying illness.

Human illness

Veterinarians and other vaccine users may be inadvertently exposed to animal vaccines as a result of unintended inoculation or spraying. Some of these vaccines may cause sickness. Veterinarians, their assistants, and other animal handlers should be especially careful when administering injectable vaccines to avoid needle-stick and eye injuries. If an individual is accidentally self-injected with a mineral oil-adjuvanted vaccine, seek immediate medical treatment regardless of the dose injected. With the notable exception of Brucellosis, these events are rarely reported. Nevertheless, accidents do occur and veterinarians should be fully aware of these risks.

Brucellosis is an existential hazard to veterinarians. The CDC has established a passive surveillance registry. In the two years 1998 to 1999, 21 individuals reported needlestick injury related exposure to the Brucella vaccine strain RB51, five were splashed in the eye, and one was splashed into an open wound. Although most received antibiotics, 19 reported clinical disease. Approximately 4 to 5 million doses of Brucella vaccines were administered annually in 1997 to 2000. It is estimated these would have resulted in at least 8000 needle-stick injuries, suggesting that exposure to RB51 is substantially under-reported.

A vaccinia recombinant rabies vaccine bait has been air-dropped across many states in the United States to vaccinate wildlife. Several instances of human exposure to these baits have been reported. (The vaccine baits have toll-free numbers printed on them.) In Ohio, there were 160 reports of bait contact and 20 of these involved contacts with the vaccine. One individual developed a severe vaccinia infection and had to be hospitalized.

Bordetella bronchiseptica causes respiratory disease in dogs and atrophic rhinitis in pigs. Infection of humans is rare but has been documented. In at least one case a young boy was inadvertently sprayed in the face with a “kennel cough vaccine.” He had been holding his dog but the dog moved. He developed a pertussis-like respiratory disease that lasted several months despite antibiotic treatment. There have been reports of clients experiencing respiratory difficulty following administration of an intranasal vaccine to their dogs.

Needle-stick injuries are not uncommon and many involve vaccines. A woman was inadvertently inoculated with the Sterne anthrax vaccine while vaccinating her horse. She did not develop anthrax but did develop a local reaction within 24 hours. Serious inflammatory reactions are associated with injected Mycobacterium paratuberculosisvaccine. Self-injections appear to be a major issue in the aquaculture industry where workers have to work fast to vaccinate slippery fish.

Ref: https://www.sciencedirect.com/science/article/pii/B9780323682992000198#st0130

Prepare for a disease X plandemic even deadlier than Covid :FDA, Bill Gates and WHO

https://fortune.com/well/2024/01/12/what-is-disease-x-world-economic-forum-pandemic-planning/

In 2018, the WHO identified nine priority diseases (listed) that pose the biggest risk to public health. They were deemed to be most risky due to a lack of treatments or their ability to cause a pandemic

https://cepi.net/cepi-funded-nipah-virus-vaccine-candidate-first-reach-phase-1-clinical-trial

https://www.yahoo.com/news/nipah-virus-first-vaccine-treat-100252591.html

This upcoming outbreak will be the Nipah virus, which is yet another lab created bioweapon brought to us courtesy of the Gain of Function all-star team of Fauci, Gates, NIH, CIA, DoD, Pentagon, CFR, UN, WHO, WEF, Rockefeller Foundation, the Wuhan Institute of Virology, etc

Source: Wikipedia, Britannica – Image, Whitecoatwasteproject-Image, OnlineMail, Gavi,

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