Artificial induction of immunity

Artificial induction of immunity is immunization achieved by human efforts in preventive healthcare, as opposed to (and augmenting) natural immunity as produced by organisms' immune systems. It makes people immune to specific diseases by means other than waiting for them to catch the disease. The purpose is to reduce the risk of death and suffering,[1] that is, the disease burden, even when eradication of the disease is not possible. Vaccination is the chief type of such immunization, greatly reducing the burden of vaccine-preventable diseases.

Immunity against infections that can cause serious illness is beneficial. Founded on a germ theory of infectious diseases, as demonstrated by Louis Pasteur's discoveries, modern medicine has provided means for inducing immunity against a widening range of diseases to prevent the associated risks from the wild infections.[1] It is hoped that further understanding of the molecular basis of immunity will translate to improved clinical practice in the future.[2]

Variolation and smallpox

The earliest recorded artificial induction of immunity in humans was by variolation or inoculation, which is the controlled infection of a subject with a less lethal natural form of smallpox (known as Variola Minor) to make him or her immune to re-infection with the more lethal natural form, Variola Major. This was practiced in ancient times in China and India, and imported into Europe, via Turkey, around 1720 by Lady Montagu and perhaps others. From England, the technique spread rapidly to the Colonies, and was also spread by African slaves arriving into Boston.[3][4]

Variolation had the disadvantage that the inoculating agent used was still an active form of smallpox and, although less potent, could still kill the inoculee or spread in its full form to others nearby. However, as the risk of death from inoculation with Variola Minor was just 1% to 2%, as compared to the 20% risk of death from the natural form of smallpox, the risks of inoculation were generally considered acceptable.[3][5][6][7][8][9]

Vaccination

In 1796, Edward Jenner FRS, a doctor and scientist who had practiced variolation, performed an experiment based on the folk-knowledge that infection with cowpox, a disease with minor symptoms which was never fatal, also conferred immunity to smallpox.[10] The idea was not new; it had been demonstrated some years earlier by Benjamin Jesty, who had not publicized his discovery.[11] In 1798, Jenner extended his observations by showing that cowpox could be passed from a lesion on one patient to others through four arm to arm transfers and that the last in the series was immune by exposing him to smallpox. Jenner described the procedure, distributed his vaccine freely, and provided information to help those hoping to establish their own vaccines. In 1798 he published his information in his famous Inquiry into the Causes and Effects...of the Cow Pox. He is credited with being the first to start detailed investigations of the subject and of bringing it to the attention of the medical profession.[12] Despite some opposition vaccination took over from variolation.

Jenner, like all members of the Royal Society in those days, was an empiricist.[13][14][15] The theory to support further advances in vaccination came later.

Germ theory

Main articles: Pasteur Louis Pasteur; Germ Theory: Germ theory of disease

In the second half of the 1800s Louis Pasteur perfected experiments which disproved the then-popular theory of spontaneous generation and from which he derived the modern theory of (infectious) disease. Using experiments based on this theory, which posited that specific microorganisms cause specific diseases, Pasteur isolated the infectious agent from anthrax. He then derived a vaccine by altering the infectious agent so as to make it harmless and then introducing this inactivated form of the infectious agents into farm animals, which then proved to be immune to the disease.[16]

Pasteur also isolated a crude preparation of the infectious agent for rabies. In a brave piece of rapid medicine development, he probably saved the life of a person who had been bitten by a clearly rabid dog by performing the same inactivating process upon his rabies preparation and then inoculating the patient with it. The patient, who was expected to die, lived, and thus was the first person successfully vaccinated against rabies.[17]

Anthrax is now known to be caused by a bacterium, and rabies is known to be caused by a virus. The microscopes of the time could reasonably be expected to show bacteria, but imaging of viruses had to wait until the development of electron microscopes with their greater resolving power in the 20th century.

Toxoids

Some diseases, such as tetanus, cause disease not by bacterial growth but by bacterial production of a toxin. Tetanus toxin is so lethal that humans cannot develop immunity to a natural infection, as the amount of toxin and time required to kill a person is much less than is required by the immune system to recognize the toxin and produce antibodies against it.[18] However the tetanus toxin is easily denatured losing its ability to produce disease, but leaving it able to induce immunity to tetanus when injected into subjects. The denatured toxin is called a toxoid.[19]

Adjuvants

The use of simple molecules such as toxoids for immunization tends to produce a low response by the immune system, and thus poor immune memory. However, adding certain substances to the mixture, for example adsorbing tetanus toxoid onto alum, greatly enhances the immune response (see Roitt etc. below). These substances are known as adjuvants. Several different adjuvants have been used in vaccine preparation. Adjuvants are also used in other ways in researching the immune system.[20]

A more contemporary approach for "boosting" the immune response to simpler immunogenic molecules (known as antigens) is to conjugate the antigens. Conjugation is the attachment to the antigen of another substance which also generates an immune response, thus amplifying the overall response and causing a more robust immune memory to the antigen. For example, a toxoid might be attached to a polysaccharide from the capsule of the bacteria responsible for most lobar pneumonia.[21][22]

Temporarily induced immunity

Platypus: monotremes lack placental transfer of immunity

Temporary immunity to a specific infection can be induced in a subject by providing the subject with externally produced immune molecules, known as antibodies or immunoglobulins. This was first performed (and is still sometimes performed) by taking blood from a subject who is already immune, isolating the fraction of the blood which contains antibodies (known as the serum), and injecting this serum into the person for whom immunity is desired. This is known as passive immunity, and the serum that is isolated from one subject and injected into another is sometimes called antiserum. Antiserum from other mammals, notably horses, has been used in humans with generally good and often life-saving results, but there is some risk of anaphylactic shock and even death from this procedure because the human body sometimes recognizes antibodies from other animals as foreign proteins.[19] Passive immunity is temporary, because the antibodies which are transferred have a lifespan of only about 3–6 months.[19] Every placental mammal (which includes humans) has experienced temporarily induced immunity by transfer of homologous antibodies from its mother across the placenta, giving it passive immunity to whatever its mother became immune to.[19][23][24] This allows some protection for the young while its own immune system is developing.

Synthetic (recombinant or cell-clone) human immunoglobulins can now be made, and for several reasons (including the risk of prion contamination of biological materials) are likely to be used more and more often. However, they are expensive to produce and are not in large-scale production as of 2013.[25] In the future it might be possible to artificially design antibodies to fit specific antigens, then produce them in large quantities to induce temporary immunity in people in advance of exposure to a specific pathogen, such as a bacterium, a virus, or a prion. At present, the science to understand this process is available but not the technology to perform it.[26]

See also

References

  1. 1 2 "Immunization". UNICEF. Archived from the original on 4 September 2019. Retrieved 26 June 2022.
  2. Palmer, Guy H.; McElwain, Terry F. (1995). "Molecular basis for vaccine development against anaplasmosis and babesiosis". Veterinary Parasitology. 57 (1–3): 233–53. doi:10.1016/0304-4017(94)03123-E. PMID 7597787.
  3. 1 2 "Variolation". Smallpox – A Great and Terrible Scourge. National Institutes of Health. Archived from the original on 2 May 2019. Retrieved 26 June 2022.
  4. White, Andrew Dickson (1898). "Theological Opposition to Inoculation, Vaccination and the use of Anaesthetics". A History of the Warfare of Science with Theology. New York: D. Appleton and Company. Archived from the original on 17 September 2008. Retrieved 26 June 2022.
  5. Boylston, A.; Williams, A. (2008). "Zabdiel Boylston's evaluation of inoculation against smallpox". Journal of the Royal Society of Medicine. 101 (9): 476–7. doi:10.1258/jrsm.2008.08k008. PMC 2587382. PMID 18779251.
  6. Lettres Philosophiques. Voltaire.
  7. In fact, the mortality rate of the Varoiola Minor form of smallpox then found in Europe was 1–3% as opposed to 30–50% for the Variola Major type found elsewhere; however, blindness, infertility, and severe scarring were common. Figures from "The Search for Immunisation", In Our Time, BBC Radio 4 (2006).
  8. Letter of Lady Montagu reproduced at "Letter of Lady Mary Montagu". Archived from the original on 2 January 2004. Retrieved 18 April 2013. viewed 18 March 2006
  9. Wolfe, R. M; Sharp, LK (2002). "Anti-vaccinationists past and present". BMJ. 325 (7361): 430–32. doi:10.1136/bmj.325.7361.430. PMC 1123944. PMID 12193361.
  10. Harris F "Edward Jenner and Vaccination" World Wide School Full text Archived 25 March 2020 at the Wayback Machine
  11. Pead, Patrick P. (2003). "Benjamin Jesty; new light in the dawn of vaccination". Lancet. 362 (9401): 2104–09. doi:10.1016/s0140-6736(03)15111-2. PMID 14697816. S2CID 4254402.
  12. Baxby, Derrick (1999). "Edward Jenner's Inquiry; a bicentenary analysis". Vaccine. 17 (4): 302–07. doi:10.1016/s0264-410x(98)00207-2. PMID 9987167.
  13. Guérin, N. (2007). "Histoire de la vaccination: De l'empirisme aux vaccins recombinants" [History of vaccination: from empiricism towards recombinant vaccines]. La Revue de Médecine Interne (in français). 28 (1): 3–8. doi:10.1016/j.revmed.2006.09.024. PMID 17092612.
  14. Vaccines – a Biography edited by Andrew W. Artenstein ISBN 978-1-4419-1107-0
  15. Gal, O.; Wolfe, C. "Empiricism and the Life Sciences in Early Modern Thought". The University of Sydney. Archived from the original on 2 January 2023. Retrieved 26 June 2022.
  16. Principles of microbiology By Alice Lorraine Smith 1985: 636 pp. https://books.google.com/books?id=5NRpAAAAMAAJ Archived 2 January 2023 at the Wayback Machine ISBN 0-8016-4685-5
  17. René Dubos, Louis Pasteur: Freelance of Science, Little, Brown and Company, 1950.
  18. "Pathogenic Clostridia, including Botulism and Tetanus (page 3)". Todar's Online Textbook of Bacteriology. Archived from the original on 15 May 2021. Retrieved 26 June 2022.
  19. 1 2 3 4 Roitt, I.M. (1977). Essential Immunology 3rd Edition. Blackwell Scientific Publications. ISBN 063200276X.
  20. "Overview". Archived from the original on 13 July 2013. Retrieved 18 April 2013.
  21. http://www.merck.com/product/usa/pi_circulars/p/pneumovax_23/pneumovax_pi.pdf Archived 2 January 2023 at the Wayback Machine
  22. Nuorti, J.P.; Whitney, C.G. (10 December 2010). Prevention of Pneumococcal Disease Among Infants and Children – Use of 13-Valent Pneumococcal Conjugate Vaccine and 23-Valent Pneumococcal Polysaccharide Vaccine (Report). Centers for Disease Control and Prevention (CDC).
  23. Ehrlich, P. (1892) Ueber Immunitaet durch Vererbung und Saeugung. Z. Hyg. Infect. Kr. 12, 183.
  24. Pitcher-Wilmott, RW; Hindocha, P; Wood, CB (1980). "The placental transfer of IgG subclasses in human pregnancy". Clinical and Experimental Immunology. 41 (2): 303–08. PMC 1537014. PMID 7438556.
  25. Engineers of small-scale humanised antibody production. Prices on application.
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