L Orrock: medical science is science fiction: January 2016

Sunday, January 31, 2016

Video explanation

I can't upload the video but it can be seen on my facebook page: Louise Orrock, with a profile picture of the Rutgers microscope sculpture.

If the page says I went to the 'London School of Economics and Social Science' the 'Social' was on the facebook webpage for LSE, which is where I did my first degree (in International Relations, 1981) and MA (Latin American Studies, 1986). After that I taught EFL/ESOL and then politics until 2012 when I accepted targeted redundancy.

Summary of argument

It is likely that most, if not all, diagnosed diseases are fictions used to control and reduce populations. First, when one looks into a microscope one is focusing on something within the microscope, not what is on the slide, because the material on the glass slide is beyond the focal length of the eye and would, in any case, be obscured by the lenses of the microscope. Second, the size a cancer or viral cell is said to be means it would be unable to do harm, no matter how many there are. Third, there is no explanation of how the instructions or information within DNA would alter living matter. Diseases kill because of policies to suppress appetite and otherwise cause harm, including by causing fear.

First, the microscope acts similarly to a kaleidoscope. Microscopes would not be able to view objects the size of cancer, viral or Ebola cells because the image would blur at the magnifications needed (as one can see from using a camera, which can bring things closer but not magnify without losing clarity, so that what one cannot see with the eye alone is not likely to exist). When someone looks into a traditional microscope, they are not, in any case, focusing on the material on the glass slide, even if the slide were sufficiently well lit and even if one’s view were not obstructed, and nor is an image of the material projected onto the screen one sees within the cylinder of the microscope, as can be observed by removing the slide, when the image remains the same. What they are observing when looking into a microscope may include the translucent and magnified lenses of their own eye but overlaying a similar looking but more crowded, relatively fixed, projected and illuminated image, whether or not it is a lens (which examination of the ends of the objective lenses suggests) or some other translucent object (at the lower end of the microscope but before the final objective lenses). Any magnification within the microscope is relatively low, ie, not significantly greater than that which can be achieved by the eye alone. This is supported by the fact that, for example, the ribbon-like objects on the screen are of a similar size to those of the lens of one’s eye that one sees in front of one in the cylinder, which are themselves not much bigger than when one views them with the eye alone when squinting into sunlight or another bright light. This is what one would expect, given that a camera blurs at a relatively low magnification.

Second, something as small as a cancer or viral or Ebola cell would not be able to travel or survive in the fluids and fluctuations of the human body or, even if it were able to, cause harm, no matter how many cells there are (as being stung by a large number of small wasps will not hurt in the same way as being stung by one large wasp and may have a protective effect, in the same way as a first injury to the body may lessen the impact of the second). Third, there is no satisfactory philosophical or scientific explanation of how the information, or instructions, contained within DNA, said to be present in every cell of the human body, can interact with and change living matter (which, other than the brain, is not said to be conscious and therefore able to ‘read’ the instructions), in other words, by what mechanism, or mechanical link, and using what force, or, if it can, in a way that is different to or greater than those changes caused by environmental factors such as nutrition or physical injury or ageing.

Diagnosed diseases kill because of factors such as fear and fatalism, inadequate nutrition (eg, food that is too salty), gas emissions (which suppress appetite as well as weakening the body), alcohol and tobacco, and extremes of temperature. Clausewitz said war was a continuation of policy by other means, but science fiction, eg, disease, is likely also to be a policy of war, intended to dominate nature (knowledge of whose intelligence has also been suppressed), promote secularism, and control and reduce populations. For example, it seems unlikely that the earth would rotate at 66,600 miles per hour around the sun or, even if it did (in some sort of cocoon), at the same time rotate at 1,000 miles per hour on its axis. If the atmosphere moved at the same speed, birds would have to fly against a 1,000 mile per hour wind or, if the atmosphere did not move, they would find themselves 0.28 miles along the road a second after they had ascended vertically into the air.

Video explanation

I can't upload a video for some reason. However, I have put one, although it's not particularly well done since I was tired from amending the leaflet and essays, onto facebook: Louise Orrock. I only have one facebook page and it has the microscope picture as my profile picture.

Friday, January 29, 2016

Photos of object within 'objective lenses'

Thursday, January 28, 2016

Bird's eye

I'm in the process of improving what I've written on microscopes. In fact, I'd wondered if the microscope contained a lens of an animal eye and when turning the microscope upside down to look into the apertures, or objective lenses, at the bottom, I saw what looked like the iris of a pigeon (in my view, if true, the pigeons in the garden will know everything that pigeon ever did before it ended up in the microscope) at the edge of the aperture - ie, it is the right size and colour. The other apertures are smaller and I haven't yet worked out from rotating the apertures whether or not it is the same or different images one sees, but I think that probably only one of the lenses contains an eye and that light may enter through other lenses. I don't think there is sufficient light to view what's on the slide, unless it is within the slide (as I can see from one of my slides, which has resembling images, one in a small second slide and one within the slide, apparently obscured by the label).

Wednesday, January 27, 2016

Amended leaflet

Photo taken outside Rutgers University, Newark, New Jersey, October 2015 (writer’s own).

First, the microscope acts similarly to a kaleidoscope. Microscopes would not be able to view objects the size of cancer, viral or Ebola cells because the image would blur at the magnifications needed (as one can see from using a camera, which can bring things closer but not magnify without losing clarity, so that what one cannot see with the eye alone is not likely to exist). When someone looks into a traditional microscope, they are not, in any case, focusing on the material on the glass slide, even if it would otherwise be visible beneath the others lenses or more vivid images within the microscope. The length of the microscope and when one squints into its light is such that the focal point of the eye is before the image on the slide. This means that the material on the slide might actually be smaller than if it were viewed by the eye alone even if it could be viewed, as objects in the distance appear smaller than those viewed at close range. What they are observing when looking into a microscope is likely to be the moving lenses of the eye but overlaying a similar but fixed, projected and illuminated object, whether or not it is a lens or some other translucent object, at the lower end of the microscope but before the final glass apertures. The magnification is relatively low and achieved by the eye alone and by the placing of the second translucent object or glass at an appropriate distance from the eyepiece, so that the microscope acts in a way that is similar to a kaleidoscope (or telescope). That one sees the lenses of the eye and of the lower microscope lens instead of the further object on the glass slide can be tested by removing the slide or rotating the final lenses and observing that the image remains the same. That the magnification is relatively low, or at least no greater than that which can be achieved by the eye itself can be seen by squinting at any light source with the eye alone, when the lenses of the eye projected and illuminated in front resemble the fixed lower image one sees looking into a microscope.

Amended viral infection

HIV infection

It seems likely that HIV is a fictitious viral infection that was invented for political reasons and that the illnesses associated with AIDS are either themselves fictitious (eg, cancer) or the result of treatment and other circumstantial factors.[1] If we set aside, as Descartes asks us to, the foundational facts of science that we have been told[2], and instead rely on observation and reasoning to decide what is most likely to be true, it seems impossible that virus cells would damage, or kill, the person. Even if one assumes that they are able to travel, despite their size, through liquids and tissues, or travel through membranes from spaces and cavities within the body, and thrive and multiply (by whatever means), and assuming that they have a motive for harming and killing the person, a virus cell that is initially imperceptible to the senses, and which remains invisible to the eye, will not possess the ability to inflict harm, whatever its number, ie, however many cells might theoretically inhabit the body at any one time (including those that may remain after their death). This is because the capacity of a large number of individual cells to inflict harm may not be substantially greater than that of the individual cell and will not be of the same magnitude as that of a larger organism of a size corresponding to that of a large number of viral cells. Even if the individual cells were able to join together to form a larger substance, as is the case, for example, with the constituent parts of a tumour or of an animal, or each produced the same toxic substance, the fact that the viral cell is invisibly small to the eye, even when a light is shone on it, implies that by whatever number it is multiplied, it will have no volume or weight and so not be capable of harm for the reason that it does not exist. When a person is sickened by, for example, the flu or the common cold, this is because the body is weak, not because it has been infected by a virus of any kind. Similarly, a person who falls ill or dies apparently of HIV infection does so because of a cumulative weakening caused by the treatment, perhaps including, but not restricted to, medication as well as other factors but not because of HIV viral infection.

First, the claim that viral cells can be viewed under a microscope needs to be treated with suspicion. Although diagnosis is by a ‘colour’ test, which it is possible now to do in the home but which needs to be sent to a laboratory for analysis, it is said to be possible to view the HIV virus cells under a microscope, either within blood samples or where the cells have been partially, or completely, isolated from bodily fluids. If, as is claimed, the virus is approximately one times ten to the minus nine metres in diameter, and if, as is claimed, a magnification of around ten thousand is needed to view the cell, the magnified image of the cell would be one hundredth of a millimetre in diameter, ie, too small to be viewed and smaller than the image of the cell apparently seen under a microscope. In any case, it is not apparent that something as small as a virus cell would exist as a particular entity, nor that anything, whatever its size, would present a clear image with such a magnification.

A thing can be divided, arithmetically, by one times ten to the negative nine, and living things and objects (such as the image on a computer screen) may be divided into very large numbers of constituent parts mathematically (geometrically), but that does not mean that anything so small that it cannot be seen by the eye exists as a complete entity. Although particular – in the sense of whole - living things may exist at an extremely small size (even if some moving life forms appear to emerge, in some conditions, at a larger size from, for example, fruit fibres), it is likely to be possible to view them clearly only at the size at which it becomes possible to view them with the eye alone.

The eye is able to see very small things clearly at close range. For example, it is possible to see with the eye alone tiny spores of mould and also tiny insects in motion. However, the eye blurs, even if it also seems to magnify, objects that are at either a greater or lesser focal length (as, for example, when a page is brought too close to the eye the letters can appear larger, as can letters at the periphery of what we are reading, but also blur). A camera lens (or telescope) can allow us to see things beyond our normal range of vision relatively clearly and distinctly. Objects beyond or closer than the object we are focusing on may appear somewhat larger but will be blurred. Also, from observation, the image of objects, such as tiny insects, will blur when the image viewed is larger than the size the objects appear when viewed by the eye alone; in other words, clarity is lost with any magnification. The magnification needed to produce a visible image of a viral cell of one times ten to the negative nine metres would, even if it were technologically possible to achieve, be such as to make the image impossible to identify as a ‘cell’.

The image of a viral cell could not be seen, to use Descartes’ phrase, clearly and distinctly. Instead, the microscope acts similarly to a kaleidoscope. When someone looks into a traditional microscope (upon which the science of diagnosed disease is based), they are not focusing on the material on the glass slide, even if it would theoretically be visible beneath, ie, not be obscured by, the lenses of the microscope, or by the more vidid image presented by the internal image, if the microscope is lit by the mirror (which does not, obviously affect focal length). The process of squinting reduces the focal length so that, given the size of the microscope, they would not see what is on the glass slide even if it would otherwise be visible beyond the lenses of the microscope. What they are observing when looking into a microscope is the moving lenses of their own eye overlaying a similar but fixed, projected and illuminated image, whether or not it is a glass lens or some other translucent object, at the lower end of the microscope but before the final glass apertures. The magnification is relatively low and achieved by the eye alone and by the placing of the second translucent object or glass at an appropriate distance from the eyepiece, so that the microscope acts in a way that is similar to a kaleidoscope or telescope.

That one sees the lenses of the eye and of the lower microscope lens instead of the further object on the glass slide can be tested by removing the slide or rotating the final lenses and observing that the image remains the same. That the magnification is relatively low, or at least no greater than that which can be achieved by the eye itself, can be seen by squinting at any light source with the eye alone, when the lenses of the eye projected and illuminated in front of one’s eyes resemble the fixed lower image one sees looking into a miroscope. In fact, if the image on the glass slide were visible it would, given the focal length of the eye, be of a smaller size than if viewed by the eye alone, since those objects beyond the focal length of the eye appear reduced in size. Also, the process of squinting into the microscope reduces the focal length, so that although a distortion of perspective of objects beyond (and before) one’s focai point might lead one to suppose the objects are larger than they would appear if viewed at close range, ie, at the appropriate focal length, the object would nevertheless be more likely to be blurred than if they were placed at the appropriate length from the eye (ie, if the microscope were shorter). Relatively limited magnification is also suggested by the fact that the image appears two dimensional (whether or not one is using two eyepieces) and that the lower image is fixed by the fact that all parts of it appear relatively clear (ie, ther eis not the blurring that one would expect if all or parts of it were moving at speed).

Second, it seems odd that HIV ‘cells’ cannot survive for long outside the human body. Why would they not, in the potentially more hospitable, and autonomous, environment (in terms of temperature, hydration, available nutrition, rest) outside the body? From observation, mould, for instance, appears to thrive in certain conditions but not noticeably within the human body, and this is true of most, if not all, living things, apart from the body’s constituent parts. What is it about virus cells that make the human body an inhospitable environment for most living organisms but the only environment hospitable to HIV virus cells? And would this not make the virus cells especially careful not to destroy their host by virtue of their number or any other means, or to alter the body significantly?

If it is because the viral cell can only live at human body temperature (although other relatively small organisms, such as fleas, can live at relatively cold temperatures, and smaller organisms seem better able to regulate their body temperature than larger ones) why would it not survive outside the body (or in other species) if the temperature approximated body temperature? And why would the temperature be correct in all climates and all physical states and throughout the body, given that body temperature can appear to vary significantly even without there necessarily being a significant change in measured temperature? And what is the body temperature of the virus?

Third, the nature of transmission seems unlikely. Why would the virus cells enter a part of the body, in the case of sexual activity, from which they might be expelled before they were able to travel, and where they would be likely to receive less in the way of nourishment perhaps (ie, where waste is about to be expelled)? If it is because they can only survive and spread by coming into contact with blood, why would this be so, given the size of the viral cell, and what would this imply about their movement within the body? If the body is able to prevent the absorption of harmful virus cells from the digestive system, despite, or because of, the small size of the virus cells, how is the virus able to leave the body of one person, enter another, survive, apparently multiply, and then travel to other parts of the body after coming into contact only with blood at, or near, the surface of the body?

For example, during sexual intercourse, the HIV cells are said to travel from the semen, blood, or vaginal discharge of one person into the blood stream of another. In the case of uncircumcised males, transmission would seem to be more likely from semen into the blood stream. How is something as small as an apparently invisible virus cell able to travel out of the semen? In the case of blood to blood transmission, how plausible is it that virus cells are able to move in blood in order, first, to leave the body of one person and, second, to multiply, remain dormant (without necessarily presenting more than ‘transient’ symptoms at the site of entry or the rest of the body), and then travel and cause harm?

From observation, a flea, larger than an apparently invisibly small 'virus cell', cannot move within even a fairly thin liquid once it has got into it without getting stuck or appearing to drown. How would a virus cell, or a number of virus cells, be able to swim within blood and discharges in order to enter the ‘lymph’, and from the lymph enter other parts of the body, especially as the spaces between ‘cells’ and cavities within the body are not said to constitute a hospitable environment, and cells would in any case at some stage need to leave the spaces or cavities in order to enter the body itself? On the other hand, if they could travel with ease within all bodily fluids, why can they not enter the body via mucous or saliva? Whatever the consistency, or viscosity, of different bodily fluids in different environments (eg, blood can vary in thickness, and colour), it seems implausible that an invisibly small virus cell, or its descendants, would be able to leave the area they have inhabited and travel within the body.

Fourth, the process of replication seems unclear. The virus is said to replicate within the human body, since the spaces between ‘cells’ and cavities within the body are not said to constitute a hospitable environment for reproduction (which is consistent with the stated fact that they cannot live outside the body and makes the explanation of cell alteration more coherent, if not more plausible). It is said to replicate by first binding to, and then entering, the host cell, and injecting its DNA (said to be converted into DNA from RNA by an agent within the host cell) into the nucleus of the host cell. It is not clear, first, how it would be able to enter the cell. The fusing of membranes would be more plausible if the viral cell and host cell were of a similar size, or the viral cell were larger, but a blood cell is said to be sixty times larger than the viral ‘capsid’. Nor is it clear why the injection of ‘DNA’ , which is information, would lead to the creation of new life, as the two have a different ontological status: ie, one is abstract (whether or not it is ‘embedded’) and one is concrete, in the sense of being living matter. Also, the explanation of replication suggests that the creation of the new viral cell is dependent upon interaction with the host cell, rather than simply finding the host a hospitable environment, even if it does not actually blur the distinction between reproduction of viral cells and alteration of host cells. That a decaying life form, including a viral cell, might produce a new organism seems possible from observation of nature. But there is no satisfactory explanation of why a viral cell, imperceptible to the senses, is able to reproduce with and otherwise alter the host cell, only an assertion that this is the case. Also, whether or not the literature attempts to explain this, it also seems implausible that either the initial cell or its offspring would be able to leave the host cell with ease in order to continue the process of reproduction and alteration of cells elsewhere in the body.

Fifth, it seems unlikely that cells would be able to replicate in sufficient numbers in areas such as lymph nodes in order later to cause harm throughout the body. If they have not been perceptible at the site of entry, how likely are they, according to common sense (which is based on our experience and memory of comparable events), to pose a threat to the rest of the body? On the other hand, if they need to alter cells in other parts of the body in order to do harm, and there also does not appear to be a clear distinction between replication and alteration of cells, is it likely that they would remain at the site of entry for up to several years, rather than travel earlier, also to make their possible eradication (for example, through surgery) less likely?

Sixth, a virus cell, if such a thing existed, would not be able to cause harm. If it can only survive in the human body, if this is the only environment in which it can obtain nourishment and which is not dangerous to it, how would destroying its host create a better environment? If the reason is that it does not expect to survive its host and gains an advantage in the short term, then, setting aside the question of whether this is how nature, as opposed to humanity, behaves, how would any number of virus cells be able to do damage to a living being? Although not said to be the case with HIV infection, one would think that subsequent exposure would be of relevance if harm increases with the number of cells present, and especially if the body becomes to any extent resistant to an earlier version of the virus . (And that the initial exposure would need to contain above a minimum number of viral cells such that below that number would pose no risk, either immediately or as a result of reproduction if introduced in a hypothetical AIDS vaccine).[3]

Assuming its motive was to obtain nourishment from the host, including from feeding on it and its nutrients, how would something as small as a virus cell be able to cause harm. From observation, fruit flies may cover the skin of, for example, an apple, but cannot penetrate it in order to gain the nourishment within it. Could any number of virus cells pass through any skin, or membrane, within the body, in order to harm its tissues or organs? Small flies may enter relatively solid fruits that have had their skins removed, but they do not appear to alter the fruit’s shape substantially or cause it to decay or dry any faster than if they were not present, and, in fact, seem to feed less on the fruit itself than the mould that appears on it as it decays, so that the flies’ effect appears to be, in some way, beneficial. But if the virus’s intention was to consume a part of the body, in which case the HIV virus is essentially the flesh eating bug that was discovered some time after the discovery of the HIV virus, how could something invisibly small erode the human body? How much damage can something invisibly small do over whatever length of time and by whatever number it is multiplied? Common sense suggests that a virus cell that cannot live outside the human body would not live for a long time or multiply rapidly and in great numbers inside it. In any case, would the virus cells not seek to regulate their number so as to maintain a hospitable environment? But, however long they lived, and however rapidly and by whatever number they multiplied, something that is initially invisible will not multiply to something with mass.

Given the size of the virus cell, the mechanism of harm could not be physical force: no matter how great their number, something as small as a virus cell – even if it existed - would not be able to overpower a host. The ‘cells’ of the body are apparently invisible to the eye but, when multiplied, make up tissue and organs, whereas HIV virus cells cannot be seen by the eye (as, for example, one sees particles of dust when a light is shone on them), whatever their number. However, even if something invisible to the eye did exist, which is unlikely, something that is so small that it is invisible would not be able to harm the body, no matter how many were present. This is because the capacity of a large number of cells to inflict harm, including as they die, is not substantially greater than that of the individual cell (as, for example, a number of very small simultaneous stings will not hurt significantly more than one sting, and as the sound of several birds singing will not be significantly louder than that of the song of one bird). A very large number of very small viral cells would therefore not be able to overwhelm the body by force, including through obstruction.

But nor would it possible for the mechanism of harm to be toxicity. Usually something toxic has a taste or a smell, for example, a food that is no longer fresh or a product that contains dead organisms (eg, ammonia), especially if it contains water. But the HIV virus is said to be a living organism that has no smell or taste, for example, when isolated in numbers on a slide. A toxin that enters the body will harm it according to the nature and amount of the toxin, usually initially, and the body will generally recover.[4] Examples of toxins include those medicines that cause unpleasant side effects and rotten food (which is likely to make the person feel unwell and which is usually expelled). From observation, it seems impossible that, since they appear to have no toxic qualities, including smell, when isolated, including after they have died, that viral cells would become so toxic within the body as to cause symptoms or kill the person.

Although the virus is said to weaken and kill cells (for example, the ‘T cells’ that normally fight infection), if the mechanism is alteration rather than cell death (which would be the case, for instance, with cancer, where the virus would presumably become an agent or catalyst, or the initial one, of cell proliferation), how would it be able to do so? How would a virus cell, or a part of it, be able to cause a harmful alteration in the tissues or organs of the human body if not by force or through some toxic quality? The process is sometimes asserted and sometimes explained in terms such that it appears to be coherent but which is either not consistent with observation of nature or seems to contradict common sense, which is an abstraction from observation[5]. Where the process is said to be mutation of host cells, there is no adequate explanation of how this happens, of the mechanism by which the viral cell is able to alter the genetic code of host cells, in the sense eiither of the nature of the mechanical link between either the viral cell and host cell or the host cell and disease-causing mutation or the agent of change if it is not physical force or toxicity. But nor could there be since the link between information, contained in DNA, and living matter is not explained, in the sense of overcoming the duality between abstract and concrete, or at least of explaining how an abstract entity can act as an agent of alteration, whether or not the RNA/DNA is said to be embedded in proteins and whether or not it is itself said to be altered by environmental factors and over time (ie, ageing).

In any case, the diseases that viral cells are said to cause are themselves likely to be fictitious. For example, there is not a consistent account of what a cancerous cell looks like, i.e., of what distinguishes it from non- malignant cells or from the tissue of benign tumours (so that a diagnosis of malignancy may be made according to invasion of surrounding tissue rather than by cell pathology), but nor is it clear how a cancerous cell can invade, or otherwise affect, surrounding cells and tissue, nor how it could break away and travel to distant organs, nor how it would ultimately kill, i.e., whether it is through the alteration, destruction, denial of nutrients, or obstruction of vital organs. It seems likely that lumps in the body, including those that we know to be present near its surface, are the result of such things as knocks, and reflect injury of some sort, such as knocks, and it is possible that some might even have a protective purpose (ie, to protect against further injury). Finally, whether or not there is an attempt to explain, rather than assert, it in the literature, nor is it clear why or how, in the sense of through what mechanism or mechanisms of causation, a viral cell would be able to cause a ‘cluster’ of different illnesses.

What kills in the case of apparently fatal illnesses such as those associated with AIDS is a cumulative weakening that may be partially caused by medication (prescription or otherwise), especially when there are initial unpleasant side effects, but which may be as likely to be caused by other factors, physical and psychological, in the environment of someone diagnosed with a viral infection (or other disease). These include such things as alcohol, tobacco, and non-prescription medications and well as narcotics, which either weaken or else stimulate and then weaken, introduce toxins into the body, cause diarrhoea[6] or constipation (which can cause headaches and occasionally fainting), encourage anorexia, depress or confuse and cause poor decision making, make one more susceptible to colds and respiratory illnesses (especially if one believes one ‘catches’ them from others), and as well to night sweats, rashes and spots, which are the body’s response to fatigue, cold, heat, dehydration or over hydration, and malnourishment, which, at the same time, the body may be less able to recognise and to respond to). Other factors include surgery, which weakens, at least temporarily, so increasing the risk from other depressants, because of anaesthesia or blood loss; poor diet (insufficient calories, food that is not fresh or rotten or includes ingredients derived from toxins); environmental factors, particularly inadequate heating, extreme heat, fluctuations in temperature, and gas emissions; excessive physical exercise or overwork, or too little exercise; insomnia, or too much sleep. In addition, and perhaps decisive, is the psychological stress and fatalism caused by the belief that one has a potentially fatal illness. As you do not need gravity to explain why things fall to earth, you do not need cancer and HIV/AIDS to explain why people who have received a diagnosis of either might eventually fall ill.

In 1985, HIV infection was reported to be the cause of a group of illnesses affecting homosexuals, heroin users, and Haitians (hhh). Although there is now a test for HIV infection that can be carried out in the home, the results still need to be obtained from a laboratory. Whether or not a vaccine would be safe and effective, apparently promising trials, for example, in Thailand ten years ago, have come to nothing. Although life expectancies for those testing ‘HIV positive’ are now said to be near normal, a diagnosis will narrow life choices and create fear. Although there is said to be a global food crisis, it seems unlikely that nature would present insurmountable problems such that humanity’s survival would depend on inventing and treating fictitious illnesses, while intended rational decisions about the targeting of individuals and populations will have been made, even on their own terms (for example, the economic and environmental consequences), in error.

[1] Thabo Mbeke, after becoming president of South Africa in 1999, changed his mind about the causes of illnesses associated with AIDS, arguing that they were not caused by HIV infection but that poverty was the main ‘co-factor’ in diagnosis.

[2]For example, that the earth travels around the sun at 66,600 miles per hour (Hutchinson and Britannica encyclopedias).

[3]If a vaccine contains a live virus cell, it is not clear why it would not itself cause harm or how if it is weakened or dead it could produce ‘antibodies’ that would be effective against subsequent exposure to the virus.?

[4]A person may become ‘used’ to a toxic substance that enters the body repeatedly. This would suggest either a purely psychological adaptation, or that the person’s physical state had changed, most plausibly that the body has weakened such that it is less responsive to the toxic nature of the substance, even if a lower exposure to a toxin does appear to confer some protection when one is exposed subsequently to larger amount.

[5]It may seem a reasonable hypothesis, for example, that every person has something within them, either an innate quality or a code (although you need to distinguish between the thing and the information, so that, for instance, injecting the code into the nucleus of a host cell would not explain replication), but how likely, or efficient, would it be for an identical code to be present in most cells of the organism?

[6]Diarrhoea is beneficial in the sense, for example, that it rids the bodies of toxins or liquid (which the body needs less of, for instance, in very hot weather). What would be the benefit to either the body or the virus of diarrhoea when both are competing for nutrients if the virus is not itself toxic (and there is no suggestion that the virus is expelled from the body)?