Immunologic adjuvant

(Redirected from Immune adjuvant)

In immunology, an adjuvant is a substance that increases or modulates the immune response to a vaccine.[1] The word "adjuvant" comes from the Latin word adiuvare, meaning to help or aid. "An immunologic adjuvant is defined as any substance that acts to accelerate, prolong, or enhance antigen-specific immune responses when used in combination with specific vaccine antigens."[2]

In the early days of vaccine manufacture, significant variations in the efficacy of different batches of the same vaccine were correctly assumed to be caused by contamination of the reaction vessels. However, it was soon found that more scrupulous cleaning actually seemed to reduce the effectiveness of the vaccines, and some contaminants actually enhanced the immune response.

There are many known adjuvants in widespread use, including aluminium salts, oils and virosomes.[3]

Overview

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Adjuvants in immunology are often used to modify or augment the effects of a vaccine by stimulating the immune system to respond to the vaccine more vigorously, and thus providing increased immunity to a particular disease. Adjuvants accomplish this task by mimicking specific sets of evolutionarily conserved molecules, so called pathogen-associated molecular patterns, which include liposomes, lipopolysaccharide, molecular cages for antigens, components of bacterial cell walls, and endocytosed nucleic acids such as RNA, double-stranded RNA, single-stranded DNA, and unmethylated CpG dinucleotide-containing DNA.[4] Because immune systems have evolved to recognize these specific antigenic moieties, the presence of an adjuvant in conjunction with the vaccine can greatly increase the innate immune response to the antigen by augmenting the activities of dendritic cells, lymphocytes, and macrophages by mimicking a natural infection.[5][6]

Types

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Inorganic adjuvants

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Aluminium salts

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There are many adjuvants, some of which are inorganic, that carry the potential to augment immunogenicity.[14][15] Alum was the first aluminium salt used for this purpose, but has been almost completely replaced by aluminium hydroxide and aluminium phosphate for commercial vaccines.[16] Aluminium salts are the most commonly-used adjuvants in human vaccines. Their adjuvant activity was described in 1926.[17]

The precise mechanism of aluminium salts remains unclear but some insights have been gained. It was formerly thought that they function as delivery systems by generating depots that trap antigens at the injection site, providing a slow release that continues to stimulate the immune system.[18] However, studies have shown that surgical removal of these depots had no impact on the magnitude of IgG1 response.[19]

Alum can trigger dendritic cells and other immune cells to secrete Interleukin 1 beta (IL‑1β), an immune signal that promotes antibody production. Alum adheres to the cell's plasma membrane and rearranges certain lipids there. Spurred into action, the dendritic cells pick up the antigen and speed to lymph nodes, where they stick tightly to a helper T cell and presumably induce an immune response. A second mechanism depends on alum killing immune cells at the injection site although researchers aren't sure exactly how alum kills these cells. It has been speculated that the dying cells release DNA which serves as an immune alarm. Some studies found that DNA from dying cells causes them to adhere more tightly to helper T cells which ultimately leads to an increased release of antibodies by B cells. No matter what the mechanism is, alum is not a perfect adjuvant because it does not work with all antigens (e.g. malaria and tuberculosis).[20] However, recent research indicates that alum formulated in a nanoparticle form rather than microparticles can broaden the utility of alum adjuvants and promote stronger adjuvant effects.[21]

Organic adjuvants

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Freund's complete adjuvant is a solution of inactivated Mycobacterium tuberculosis in mineral oil developed in 1930. It is not safe enough for human use. A version without the bacteria, that is only oil in water, is known as Freund's incomplete adjuvant. It helps vaccines release antigens for a longer time. Despite the side effects, its potential benefit has led to a few clinical trials.[17]

Squalene is a naturally-occurring organic compound used in human and animal vaccines. Squalene is an oil, made up of carbon and hydrogen atoms, produced by plants and is present in many foods. Squalene is also produced by the human liver as a precursor to cholesterol and is present in human sebum.[22] MF59 is an oil-in-water emulsion of squalene adjuvant used in some human vaccines. As of 2021, over 22 million doses of one vaccine with squalene, FLUAD, have been administered with no severe adverse effects reported.[23] AS03 is another squalene-containing adjuvant.[24] In addition, squalene-based O/W emulsions have also been shown to stably incorporate small molecule TLR7/8 adjuvants (e.g. PVP-037) and lead to enhanced adjuvanticity via synergism.[13]

The plant extract QS-21 is a liposome made up of two plant saponins from Quillaja saponaria, a Chilean soap bark tree.[25][26]

Monophosphoryl lipid A (MPL), a detoxified version of the lipopolysaccharide from the bacterium Salmonella Minnesota, interacts with the receptor TLR4 to enhance immune response.[27][17]

The combination of QS-21, cholesterol and MPL forms the adjuvant AS01[11] which is used in the Shingrix vaccine approved in 2017,[27] as well as in the approved malaria vaccine Mosquirix.[11]

The adjuvant Matrix-M is an immune stimulating complex (ISCOM) consisting of nanospheres made of QS-21, cholesterol and phospholipids.[26] It is used in the approved Novavax Covid-19 vaccine and in the malaria vaccine R21/Matrix-M.

Several unmethylated cytosine phosphoguanosine (CpG) oligonucleotides activate the TLR9 receptor that is present in a number of cell types of the immune system. The adjuvant CpG 1018 is used in an approved Hepatitis B vaccine.[11]

Adaptive immune response

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In order to understand the links between the innate immune response and the adaptive immune response to help substantiate an adjuvant function in enhancing adaptive immune responses to the specific antigen of a vaccine, the following points should be considered:

  • Innate immune response cells such as dendritic cells engulf pathogens through a process called phagocytosis.
  • Dendritic cells then migrate to the lymph nodes where T cells (adaptive immune cells) wait for signals to trigger their activation.[28]
  • In the lymph nodes, dendritic cells mince the engulfed pathogen and then express the pathogen clippings as antigen on their cell surface by coupling them to a special receptor known as a major histocompatibility complex.
  • T cells can then recognize these clippings and undergo a cellular transformation resulting in their own activation.[29]
  • γδ T cells possess characteristics of both the innate and adaptive immune responses.
  • Macrophages can also activate T cells in a similar approach (but do not do so naturally).

This process carried out by both dendritic cells and macrophages is termed antigen presentation and represents a physical link between the innate and adaptive immune responses.

Upon activation, mast cells release heparin and histamine to effectively increase trafficking to and seal off the site of infection to allow immune cells of both systems to clear the area of pathogens. In addition, mast cells also release chemokines which result in the positive chemotaxis of other immune cells of both the innate and adaptive immune responses to the infected area.[30][31]

Due to the variety of mechanisms and links between the innate and adaptive immune response, an adjuvant-enhanced innate immune response results in an enhanced adaptive immune response. Specifically, adjuvants may exert their immune-enhancing effects according to five immune-functional activities.[32]

  • First, adjuvants may help in the translocation of antigens to the lymph nodes where they can be recognized by T cells. This will ultimately lead to greater T cell activity resulting in a heightened clearance of pathogen throughout the organism.
  • Second, adjuvants may provide physical protection to antigens which grants the antigen a prolonged delivery. This means the organism will be exposed to the antigen for a longer duration, making the immune system more robust as it makes use of the additional time by upregulating the production of B and T cells needed for greater immunological memory in the adaptive immune response.
  • Third, adjuvants may help to increase the capacity to cause local reactions at the injection site (during vaccination), inducing greater release of danger signals by chemokine releasing cells such as helper T cells and mast cells.
  • Fourth, they may induce the release of inflammatory cytokines which helps to not only recruit B and T cells at sites of infection but also to increase transcriptional events leading to a net increase of immune cells as a whole.
  • Finally, adjuvants are believed to increase the innate immune response to antigen by interacting with pattern recognition receptors (PRRs) on or within accessory cells.[11]

Toll-like receptors

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The ability of the immune system to recognize molecules that are broadly shared by pathogens is, in part, due to the presence of immune receptors called toll-like receptors (TLRs) that are expressed on the membranes of leukocytes including dendritic cells, macrophages, natural killer cells, cells of the adaptive immunity (T and B lymphocytes) and non-immune cells (epithelial and endothelial cells, and fibroblasts).[33]

The binding of ligands – either in the form of adjuvant used in vaccinations or in the form of invasive moieties during times of natural infection – to TLRs mark the key molecular events that ultimately lead to innate immune responses and the development of antigen-specific acquired immunity.[34][35]

As of 2016, several TLR ligands were in clinical development or being tested in animal models as potential adjuvants.[36]

Medical complications

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Humans

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Aluminium salts used in many human vaccines are regarded as safe by Food and Drug Administration.[37] Although there are studies suggesting the role of aluminium, especially injected highly bioavailable antigen-aluminium complexes when used as adjuvant, in Alzheimer's disease development,[38] the majority of researchers do not support a causal connection with aluminium.[39] Adjuvants may make vaccines too reactogenic, which often leads to fever. This is often an expected outcome upon vaccination and is usually controlled in infants by over-the-counter medication if necessary.

An increased number of narcolepsy (a chronic sleep disorder) cases in children and adolescents was observed in Scandinavian and other European countries after vaccinations to address the H1N1 "swine flu" pandemic in 2009. Narcolepsy has previously been associated with HLA-subtype DQB1*602, which has led to the prediction that it is an autoimmune process. After a series of epidemiological investigations, researchers found that the higher incidence correlated with the use of AS03-adjuvanted influenza vaccine (Pandemrix). Those vaccinated with Pandemrix have almost a twelve-times higher risk of developing the disease.[40][41] The adjuvant of the vaccine contained vitamin E that was no more than a day's normal dietary intake. Vitamin E increases hypocretin-specific fragments that bind to DQB1*602 in cell culture experiments, leading to the hypothesis that autoimmunity may arise in genetically susceptible individuals,[42] but there is no clinical data to support this hypothesis. The third AS03 ingredient is polysorbate 80.[24] Polysorbate 80 is also found in both the Oxford–AstraZeneca and Janssen COVID-19 vaccines.[43][44]

Animals

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Aluminium adjuvants have caused motor neuron death in mice[45] when injected directly onto the spine at the scruff of the neck, and oil–water suspensions have been reported to increase the risk of autoimmune disease in mice.[46] Squalene has caused rheumatoid arthritis in rats already prone to arthritis.[47]

In cats, vaccine-associated sarcoma (VAS) occurs at a rate of 1–10 per 10,000 injections. In 1993, a causal relationship between VAS and administration of aluminium adjuvated rabies and FeLV vaccines was established through epidemiologic methods, and in 1996 the Vaccine-Associated Feline Sarcoma Task Force was formed to address the problem.[48] However, evidence conflicts on whether types of vaccines, manufacturers or factors have been associated with sarcomas.[49]

Controversy

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TLR signaling

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As of 2006, the premise that TLR signaling acts as the key node in antigen-mediated inflammatory responses has been in question as researchers have observed antigen-mediated inflammatory responses in leukocytes in the absence of TLR signaling.[4][50] One researcher found that in the absence of MyD88 and Trif (essential adapter proteins in TLR signaling), they were still able to induce inflammatory responses, increase T cell activation and generate greater B cell abundancy using conventional adjuvants (alum, Freund's complete adjuvant, Freund's incomplete adjuvant, and monophosphoryl-lipid A/trehalose dicorynomycolate (Ribi's adjuvant)).[4]

These observations suggest that although TLR activation can lead to increases in antibody responses, TLR activation is not required to induce enhanced innate and adaptive responses to antigens.

Investigating the mechanisms which underlie TLR signaling has been significant in understanding why adjuvants used during vaccinations are so important in augmenting adaptive immune responses to specific antigens. However, with the knowledge that TLR activation is not required for the immune-enhancing effects caused by common adjuvants, we can conclude that there are, in all likelihood, other receptors besides TLRs that have not yet been characterized, opening the door to future research.

Safety

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Reports after the first Gulf War linked anthrax vaccine adjuvants[51] to Gulf War syndrome in American and British troops.[52] The United States Department of Defense strongly denied the claims.

Discussing the safety of squalene as an adjuvant in 2006, the World Health Organisation stated "follow-up to detect any vaccine-related adverse events will need to be performed."[53] No such followup has been published by the WHO.

Subsequently, the American National Center for Biotechnology Information published an article discussing the comparative safety of vaccine adjuvants which stated that "the biggest remaining challenge in the adjuvant field is to decipher the potential relationship between adjuvants and rare vaccine adverse reactions, such as narcolepsy, macrophagic myofasciitis or Alzheimer's disease."[54]

See also

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References

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  1. ^ "Guideline on Adjuvants in Vaccines for Human Use" (PDF). The European Medicines Agency. Archived (PDF) from the original on 14 June 2018. Retrieved 8 May 2013.
  2. ^ Sasaki S, Okuda K (2000). "The Use of Conventional Immunologic Adjuvants in DNA Vaccine Preparations". In Lowrie DB, Whalen RG (eds.). DNA Vaccines: Methods and Protocols. Methods in Molecular Medicine. Vol. 29. Humana Press. pp. 241–250. doi:10.1385/1-59259-688-6:241. ISBN 978-0896035805. PMID 21374324.
  3. ^ Travis K (January 2007). "Deciphering Immunology's Dirty Secret". The Scientist. Archived from the original on 2020-08-09. Retrieved 2018-09-14.
  4. ^ a b c Gavin AL, Hoebe K, Duong B, Ota T, Martin C, Beutler B, et al. (December 2006). "Adjuvant-enhanced antibody responses in the absence of toll-like receptor signaling". Science. 314 (5807): 1936–1938. Bibcode:2006Sci...314.1936G. doi:10.1126/science.1135299. PMC 1868398. PMID 17185603.
  5. ^ Majde JA, ed. (1987). Immunopharmacology of infectious diseases: vaccine adjuvants and modulators of non-specific resistance. Progress in leukocyte biology. Vol. 6. Alan R. Liss. ISBN 978-0845141052.
  6. ^ "Immunization schedule in India 2016". Superbabyonline. Archived from the original on 28 June 2021. Retrieved 5 May 2016.
  7. ^ a b c d e f Guimarães LE, Baker B, Perricone C, Shoenfeld Y (October 2015). "Vaccines, adjuvants and autoimmunity". Pharmacological Research. 100: 190–209. doi:10.1016/j.phrs.2015.08.003. PMC 7129276. PMID 26275795.
  8. ^ El Ashry ES, Ahmad TA (December 2012). "The use of propolis as vaccine's adjuvant". Vaccine. 31 (1): 31–39. doi:10.1016/j.vaccine.2012.10.095. PMID 23137844.
  9. ^ Jones SV (19 September 1964). "Peanut Oil Used in a New Vaccine". New York Times. Archived from the original on 9 August 2021. Retrieved 27 August 2017.
  10. ^ Smith JW, Fletcher WB, Peters M, Westwood M, Perkins FJ (April 1975). "Response to influenza vaccine in adjuvant 65-4". The Journal of Hygiene. 74 (2): 251–259. doi:10.1017/s0022172400024323. PMC 2130368. PMID 1054729.
  11. ^ a b c d e f Pulendran B, S Arunachalam P, O'Hagan DT (June 2021). "Emerging concepts in the science of vaccine adjuvants". Nature Reviews. Drug Discovery. 20 (6): 454–475. doi:10.1038/s41573-021-00163-y. PMC 8023785. PMID 33824489.
  12. ^ "COVAXIN® (BBV152) – Inactivated, COVID-19 vaccine". www.who.int. Retrieved 2024-07-14.
  13. ^ a b Soni D, Borriello F, Scott DA, Feru F, DeLeon M, Brightman SE, et al. (July 2024). "From hit to vial: Precision discovery and development of an imidazopyrimidine TLR7/8 agonist adjuvant formulation". Science Advances. 10 (27): eadg3747. doi:10.1126/sciadv.adg3747. PMC 11221515. PMID 38959314.
  14. ^ Clements CJ, Griffiths E (May 2002). "The global impact of vaccines containing aluminium adjuvants". Vaccine. 20 (Suppl 3): S24–S33. doi:10.1016/s0264-410x(02)00168-8. PMID 12184361.
  15. ^ Glenny A, Pope C, Waddington H, Wallace U (1926). "The antigenic value of toxoid precipitated by potassium alum". J Pathol Bacteriol. 29: 38–45.
  16. ^ Marrack P, McKee AS, Munks MW (April 2009). "Towards an understanding of the adjuvant action of aluminium". Nature Reviews. Immunology. 9 (4): 287–293. doi:10.1038/nri2510. PMC 3147301. PMID 19247370.
  17. ^ a b c Apostólico JD, Lunardelli VA, Coirada FC, Boscardin SB, Rosa DS (2016). "Adjuvants: Classification, Modus Operandi, and Licensing". Journal of Immunology Research. 2016: 1459394. doi:10.1155/2016/1459394. PMC 4870346. PMID 27274998.
  18. ^ Leroux-Roels G (August 2010). "Unmet needs in modern vaccinology: adjuvants to improve the immune response". Vaccine. 28 (Suppl 3): C25–C36. doi:10.1016/j.vaccine.2010.07.021. PMID 20713254.
  19. ^ Hutchison S, Benson RA, Gibson VB, Pollock AH, Garside P, Brewer JM (March 2012). "Antigen depot is not required for alum adjuvanticity". FASEB Journal. 26 (3): 1272–1279. doi:10.1096/fj.11-184556. PMC 3289510. PMID 22106367.
  20. ^ Leslie M (July 2013). "Solution to vaccine mystery starts to crystallize". Science. 341 (6141): 26–27. Bibcode:2013Sci...341...26L. doi:10.1126/science.341.6141.26. PMID 23828925.
  21. ^ Nazarizadeh A, Staudacher AH, Wittwer NL, Turnbull T, Brown MP, Kempson I (April 2022). "Aluminium Nanoparticles as Efficient Adjuvants Compared to Their Microparticle Counterparts: Current Progress and Perspectives". International Journal of Molecular Sciences. 23 (9): 4707. doi:10.3390/ijms23094707. PMC 9101817. PMID 35563097.
  22. ^ Del Giudice G, Fragapane E, Bugarini R, Hora M, Henriksson T, Palla E, et al. (September 2006). "Vaccines with the MF59 adjuvant do not stimulate antibody responses against squalene". Clinical and Vaccine Immunology. 13 (9): 1010–1013. doi:10.1128/CVI.00191-06. PMC 1563566. PMID 16960112.
  23. ^ "Squalene-based adjuvants in vaccines". WHO. Archived from the original on November 4, 2012. Retrieved 2019-01-10.
  24. ^ a b Pandemrix – Summary of product characteristics Archived October 7, 2009, at the Wayback Machine, European Medicines Agency website European Medicines Agency website Archived 2013-07-15 at the Wayback Machine
  25. ^ Alving CR, Beck Z, Matyas GR, Rao M (June 2016). "Liposomal adjuvants for human vaccines". Expert Opinion on Drug Delivery. 13 (6): 807–816. doi:10.1517/17425247.2016.1151871. PMID 26866300. S2CID 30639153.
  26. ^ a b Stertman L, Palm AE, Zarnegar B, Carow B, Lunderius Andersson C, Magnusson SE, et al. (December 2023). "The Matrix-M™ adjuvant: A critical component of vaccines for the 21st century". Human Vaccines & Immunotherapeutics. 19 (1): 2189885. doi:10.1080/21645515.2023.2189885. PMC 10158541. PMID 37113023.
  27. ^ a b "Shingrix package insert" (PDF). Food and Drug Administration. Archived (PDF) from the original on 24 April 2019. Retrieved 7 April 2019.
  28. ^ Bousso P, Robey E (June 2003). "Dynamics of CD8+ T cell priming by dendritic cells in intact lymph nodes". Nature Immunology. 4 (6): 579–585. doi:10.1038/ni928. PMID 12730692. S2CID 26642061.
  29. ^ Mempel TR, Henrickson SE, Von Andrian UH (January 2004). "T-cell priming by dendritic cells in lymph nodes occurs in three distinct phases". Nature. 427 (6970): 154–159. Bibcode:2004Natur.427..154M. doi:10.1038/nature02238. PMID 14712275.
  30. ^ Gaboury JP, Johnston B, Niu XF, Kubes P (January 1995). "Mechanisms underlying acute mast cell-induced leukocyte rolling and adhesion in vivo". Journal of Immunology. 154 (2): 804–813. doi:10.4049/jimmunol.154.2.804. PMID 7814884. S2CID 17839603.
  31. ^ Kashiwakura J, Yokoi H, Saito H, Okayama Y (October 2004). "T cell proliferation by direct cross-talk between OX40 ligand on human mast cells and OX40 on human T cells: comparison of gene expression profiles between human tonsillar and lung-cultured mast cells". Journal of Immunology. 173 (8): 5247–5257. doi:10.4049/jimmunol.173.8.5247. PMID 15470070.
  32. ^ Schijns VE (August 2000). "Immunological concepts of vaccine adjuvant activity". Current Opinion in Immunology. 12 (4): 456–463. doi:10.1016/S0952-7915(00)00120-5. PMID 10899018.
  33. ^ Delneste Y, Beauvillain C, Jeannin P (January 2007). "[Innate immunity: structure and function of TLRs]". Médecine/Sciences. 23 (1): 67–73. doi:10.1051/medsci/200723167. PMID 17212934.
  34. ^ Takeda K, Akira S (January 2005). "Toll-like receptors in innate immunity". International Immunology. 17 (1): 1–14. doi:10.1093/intimm/dxh186. PMID 15585605.
  35. ^ Medzhitov R, Preston-Hurlburt P, Janeway CA (July 1997). "A human homologue of the Drosophila Toll protein signals activation of adaptive immunity". Nature. 388 (6640): 394–397. Bibcode:1997Natur.388..394M. doi:10.1038/41131. PMID 9237759. S2CID 4311321.
  36. ^ Toussi DN, Massari P (April 2014). "Immune Adjuvant Effect of Molecularly-defined Toll-Like Receptor Ligands". Vaccines. 2 (2): 323–353. doi:10.3390/vaccines2020323. PMC 4494261. PMID 26344622.
  37. ^ Baylor NW, Egan W, Richman P (May 2002). "Aluminum salts in vaccines--US perspective". Vaccine. 20 (Suppl 3): S18–S23. doi:10.1016/S0264-410X(02)00166-4. PMID 12184360.
  38. ^ Tomljenovic L (2010). "Aluminum and Alzheimer's disease: after a century of controversy, is there a plausible link?". Journal of Alzheimer's Disease. 23 (4): 567–598. doi:10.3233/JAD-2010-101494. PMID 21157018.
  39. ^ Lidsky TI (May 2014). "Is the Aluminum Hypothesis dead?". Journal of Occupational and Environmental Medicine. 56 (5 Suppl): S73–S79. doi:10.1097/jom.0000000000000063. PMC 4131942. PMID 24806729.
  40. ^ Miller E, Andrews N, Stellitano L, Stowe J, Winstone AM, Shneerson J, et al. (February 2013). "Risk of narcolepsy in children and young people receiving AS03 adjuvanted pandemic A/H1N1 2009 influenza vaccine: retrospective analysis". BMJ. 346 (feb26 2): f794. doi:10.1136/bmj.f794. PMID 23444425.
  41. ^ Nohynek H, Jokinen J, Partinen M, Vaarala O, Kirjavainen T, Sundman J, et al. (2012-03-28). "AS03 adjuvanted AH1N1 vaccine associated with an abrupt increase in the incidence of childhood narcolepsy in Finland". PLOS ONE. 7 (3). Benjamin J. Cowling (ed.): e33536. Bibcode:2012PLoSO...733536N. doi:10.1371/journal.pone.0033536. PMC 3314666. PMID 22470453.
  42. ^ Masoudi S, Ploen D, Kunz K, Hildt E (May 2014). "The adjuvant component α-tocopherol triggers via modulation of Nrf2 the expression and turnover of hypocretin in vitro and its implication to the development of narcolepsy". Vaccine. 32 (25): 2980–2988. doi:10.1016/j.vaccine.2014.03.085. PMID 24721530.
  43. ^ "Emergency Use Authorization (EUA) of the Jansen COVID-19 Vaccine to Prevent Coronavirus Dusease 2019 (COVID-19) in Individuals 18 Years of Age and Older". Food and Drug Administration. Archived from the original on 2023-08-02. Retrieved 2021-04-06.
  44. ^ "AstraZeneca COVID-19 Vaccine". dailymed.nlm.nih.gov. Archived from the original on 2022-10-13. Retrieved 2021-04-06.
  45. ^ Petrik MS, Wong MC, Tabata RC, Garry RF, Shaw CA (2007). "Aluminum adjuvant linked to Gulf War illness induces motor neuron death in mice". Neuromolecular Medicine. 9 (1): 83–100. doi:10.1385/NMM:9:1:83. PMID 17114826. S2CID 15839936.
  46. ^ Satoh M, Kuroda Y, Yoshida H, Behney KM, Mizutani A, Akaogi J, et al. (August 2003). "Induction of lupus autoantibodies by adjuvants". Journal of Autoimmunity. 21 (1): 1–9. doi:10.1016/S0896-8411(03)00083-0. PMID 12892730.
  47. ^ Carlson BC, Jansson AM, Larsson A, Bucht A, Lorentzen JC (June 2000). "The endogenous adjuvant squalene can induce a chronic T-cell-mediated arthritis in rats". The American Journal of Pathology. 156 (6): 2057–2065. doi:10.1016/S0002-9440(10)65077-8. PMC 1850095. PMID 10854227. Archived from the original on 2003-11-21.
  48. ^ Richards JR, Elston TH, Ford RB, Gaskell RM, Hartmann K, Hurley KF, et al. (November 2006). "The 2006 American Association of Feline Practitioners Feline Vaccine Advisory Panel report". Journal of the American Veterinary Medical Association. 229 (9): 1405–1441. doi:10.2460/javma.229.9.1405. PMID 17078805.
  49. ^ Kirpensteijn J (October 2006). "Feline injection site-associated sarcoma: Is it a reason to critically evaluate our vaccination policies?". Veterinary Microbiology. 117 (1): 59–65. doi:10.1016/j.vetmic.2006.04.010. PMID 16769184.
  50. ^ Wickelgren I (December 2006). "Immunology. Mouse studies question importance of toll-like receptors to vaccines". Science. 314 (5807): 1859–1860. doi:10.1126/science.314.5807.1859a. PMID 17185572. S2CID 31553418.
  51. ^ Butler D (November 1997). "Admission on Gulf War vaccines spurs debate on medical records". Nature. 390 (6655): 3–4. Bibcode:1997Natur.390Q...3B. doi:10.1038/36158. PMID 9363878. S2CID 5116290.
  52. ^ "Illegal vaccine link to Gulf war syndrome". TheGuardian.com. 30 July 2001. Archived from the original on 10 May 2023. Retrieved 20 September 2020.
  53. ^ The Global Advisory Committee on Vaccine Safety (21 July 2006). "Squalene-based adjuvants in vaccines". Archived from the original on November 4, 2012.
  54. ^ Petrovsky N (November 2015). "Comparative Safety of Vaccine Adjuvants: A Summary of Current Evidence and Future Needs". Drug Safety. 38 (11): 1059–1074. doi:10.1007/s40264-015-0350-4. PMC 4615573. PMID 26446142.
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