The Vaccine Question

What is a cold?

We have spent the last year or so picking apart various aspects of the multifaceted global war in an attempt to better define what is real and what is not. Until now we have felt poorly equipped to tackle the issue of Covid-19 vaccines. Not least because there are heavily pro and anti camps who hold no hostages when it comes to dipping a toe in to one side or the other. Out of necessity we have remained aloof, but all the while gathering data, researching what we suspect to be the real causes of Covid-19 and other illnesses. Now the research on arsenic and radiation is well covered, we can apply that knowledge in analysing the side effects lists.

This article will look at the real function of cold and influenza symptoms, why the body does not seem to recognise Covid-19 as a tangible immune cascade-worthy ‘virus’, and why that creates holes in the supposed mechanism provided by the vaccines. The following article will look at how and why we believe some people experience catastrophic events when they receive the vaccines, and at first glance of the Astra Zeneca and Pfizer results, what differences appear. We will then look at how exposure to arsine and radiation may exacerbate severe reactions. Reviewing historic exposures to arsine/radiation over the UK concurrent with the rollout timeline may also reveal patterns.

Most of us experience a ‘cold’ at least once a year. This usually exhibits with tingling in the nose, sneezing, and rhinorrhoea (runny nose). We might experience a cough, which begins with irritation and sore, dry throat, progressing to a more mucus filled productive cough. A ‘cold’ can last a day or two, or can drag out for a couple of weeks.

Then there is the other type of common illness, a stomach upset. We might feel a little queazy for a few days, not have much of an appetite, which may reach a peak of vomiting and/or diarrhoea, or vomiting and diarrhoea can arrive very suddenly. Children seem to experience bouts of all the above types of sickness more regularly than adults.

Influenza is more rare, perhaps we might experience a bout just once or twice in our life time. It usually manifests with an overall feeling of malaise, fever, headaches and cough. Fever is usually accompanied by body aches and rigours (shivering). Nausea, vomiting and diarrhoea may also be included with or without mucus production from the respiratory tract. In some severe cases of influenza, ‘viral’ pneumonia, bacterial infections or other complications may occur.

In the scientific world a ‘cold’ is attributed to a ‘virus’ - rhinovirus, coronavirus and other strains. We never get tested for these, as colds are usually ‘self-limiting’ mild diseases and we perk right up as soon as the symptoms have gone. A similar thing is thought of with regard to stomach upsets, particularly in acute presentations. Children are kept home from school for 48 hours so they do not ‘spread’ the stomach ‘bug’. Sometimes, if the stomach upset lingers and results in vomiting, diarrhoea and dehydration, a clinician might suspect food poisoning in the form of bacterial poisoning such as E Coli, or Norovirus. Rarely would they look at chemical poisoning unless the occupation of the person involved indicated this may be an issue.

The general premise is that we catch these ‘bugs’ from other people, which then multiply in our bodies and make us sick, some quicker than others. Clinicians seem mainly concerned with the action of being sick or having a cough or runny nose. The physical manifestation of illness is, in clinical circles, a sign that a body is riddled with virus or bacteria and the patient may be contagious to others. Then of course, often in school and work settings, a small cluster of sickness may appear, which supports the theory of contagion.

Let’s unpack how these symptom sets occur and why.

Sneezing

Sneezing is the first signal that the body is being exposed to an antigen or pathogen in the form of a physical particle. An antigen is an invading particle, organism or molecule which creates an antibody response, a pathogen can be virus, bacteria, parasite or fungi, which may or may not induce antibodies. For ease we are using the term antigen in this article. Sneezing when antigens are present in the nose is an innate protective reflex produced by irritation to the mucous membranes, which in turn signal, via neuropeptides to the brain stem, to produce a sneeze, according to Liu et al (2021). The part of the brain stem that governs sneezing interestingly is not connected to the areas governing respiration.

Following sneezing, if the antigen is not expelled sufficiently or antigens continue to invade, an initial immune response begins. The molecule that signals to the brain stem after a sneeze is called neuromedin B (NMB), which together with it’s receptor (NMBR), has been documented to be involved in initiating an immune response to ‘Influenza A’. It triggers interferon alpha (IFN a) to prime CD4+ T cell memory, allowing the immune system to alter it’s response to this particular antigen when exposed.