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Nasal vaccine

January 01, 1970

A nasal vaccine is a vaccine administered through the nose that stimulates an immune response without an injection. It induces immunity through the inner surface of the nose, a surface that naturally comes in contact with many airborne microbes.[1] Nasal vaccines are emerging as an alternative to injectable vaccines because they do not use needles and can be introduced through the mucosal route. Nasal vaccines can be delivered through nasal sprays to prevent respiratory infections, such as influenza.

History edit

Nasal inoculation dates as far back as the 17th century in China during the Kangxi Emperor’s reign. Documentation during this period indicates that the Kangxi Emperor vaccinated his family, army, and others for mild smallpox. Manuals detailing vaccination techniques at the time all focused on sending smallpox up the nose of the individual being vaccinated. Although other vaccination techniques were developed using an infected individual’s scabs, a common method was to place a cotton swab with the fluid from an infected person’s pustule up the nose.[2]

Following smallpox, influenza became a prominent focus for nasal vaccine development. The first live attenuated influenza vaccine (LAIV) in the form of a nasal spray was created in Russia by the Institute of Experimental Medicine in 1987. This nasal vaccine development was based on the Russian backbone of LAIV while nasal vaccines since then have been based on other LAIV backbones.[3] The first nasal influenza vaccine was released in the United States in 2001 but was taken off the market due to toxicity concerns. FluMist, one of the most prominent nasal LAIVs, was released in 2003 as nasal LAIVs continued developing.[4]

Nasal vaccine
 
Application of an intranasal mist of the flu vaccine
SpecialtyVaccine delivery
[edit on Wikidata]

Anthrax attacks at the beginning of the 21st century caused a demand for nasal vaccine development. As anthrax is an airborne substance that can be inhaled, a nasal vaccine has the potential to be used to protect individuals from the effects it can have on the respiratory system.[5] Following the September 11, 2001 terrorist attacks in the United States, several individuals at news stations and U.S. senators died after being sent letters with anthrax as an act of bioterrorism.[6] Nasal vaccine research and development against anthrax was encouraged by the U.S. government in an effort to vaccinate troops.[5][7] BioThrax, the current anthrax vaccine that is licensed and administered in the United States, requires up to five intramuscular injections and annual boosters; research within the past decade has developed an alternative nasal vaccine that follows the path of infection for anthrax and induces both humoral and cellular immune responses.[5]

The global COVID-19 pandemic led to a rise in nasal vaccines against coronavirus. International efforts for vaccine development occurred as countries such as India, IranRussia, and China created nasal COVID-19 vaccines.[citation needed]

Administration edit

Nasal vaccines are a subsection of mucosal immunization as they use a mucosal route for vaccine delivery. As many pathogens can enter the body through the nose, nasal vaccines take advantage of this mechanism to deliver the vaccine. The nose has multiple lines of defense to prevent pathogens from entering further into the body. Nasal hairs are the first defense as they are at the entrance of the nose and prevent large particles from entering. The mucus layer in the nasal cavity can trap smaller particles that get past the nose hairs.[8] The nasal cavity has a large vascularization network so particles can go through the epithelial layer and directly enter the bloodstream.[9] Intruding particles will interact with the mucosal immune system if they reach the nasal mucosa. The mucosal immune system is composed of lymphoid tissue, B cells, T cells, and antigen-presenting cells. These different types of cells work together to identify intruding particles and trigger an immune response.[8] Nasal vaccines must overcome these barriers and get clearance to deliver the viral antigen to patients.[4] Nasal vaccines must overcome these barriers and get clearance to deliver the viral antigen to patients.[10]

Nasal vaccines can come in different forms such as solutions (liquids), powders, gels, and solid inserts. The most prevalent type of nasal vaccine in research and clinical application is solutions due to its ease of use. Although solutions are usually pipetted into test subjects’ nostrils when conducting animal trials for nasal vaccines, nasal sprays are considered the most practical approach for mass human vaccination using nasal vaccines.[8] A nasal spray is able to bypass the initial layers of the nasal mucosa and deliver the vaccine particles directly to the mucoadhesive layer.[11] The antigen in the nasal vaccine can then trigger an immune response and prevent infection due to nasal vaccines’ accessibility to the immune system.[12][13]

 
Human Nasal Anatomy

Nasal sprays are commonly used for delivering drugs in addition to vaccines. Decongestant drugs are often directly delivered to the nose through nasal sprays. Cold and allergy medication can be administered using nasal sprays for local delivery by bypassing nasal hairs and being introduced to the nasal cavity. Intranasal administration can have less drug degradation compared to oral administration because of direct particle delivery. Peptide drugs used for hormone treatments can be delivered nasally through nasal sprays instead of orally to retain particle integrity. Nasal sprays can also be used to deliver diabetes treatment, steroids, and intranasal oxytocin to induce labor. Nasal administration is also used to deliver anesthetics and sedatives due to direct access to the mucosal immune system and bloodstream.[14]

The olfactory epithelium makes up approximately 7% of the surface area of the nasal cavity and is connected to the olfactory bulb in the brain. Drugs and vaccines can be delivered to the brain past the blood-brain barrier through olfactory nerve cells.[14]

Compared to injectable vaccines, nasal vaccines can be advantageous because they are safe, painless, and easy to use. Nasal vaccines do not require a needle, which eliminates pain from needlestick injuries and safety concerns due to cross-contamination and needle disposal. Some studies also show that intranasal vaccines can generate cross-reactive antibodies that could lead to cross-protection.[8]

Live attenuated influenza vaccine edit

Main article: Live attenuated influenza vaccine

The live attenuated influenza vaccine (LAIV) in the form of a nasal spray was one of the first nasal vaccines released on the market. Nasal spray LAIVs have been used since the late 1980s as an alternative to the injectable influenza vaccine.[3] Nasal influenza vaccines have become popular as they reduce the risk of intramuscular injuries from administration and are painless. They can also be given more easily to patients because they do not require a needle.

 
FluMist Quadrivalent

The most prominent nasal LAIV is FluMist, which was released in 2003.[4] FluMist, officially known as FluMist Quadrivalent in the United States and Fluenz in Europe, is known to be the only flu vaccine on the market that does not use a needle.[15] All nasal LAIVs for recent flu seasons (2022-2023) are considered quadrivalents because “they are designed to protect against four types of flu viruses: an influenza A(H1N1) virus, an influenza A(H3N2) virus and two influenza B viruses.”[16] Although injectable and nasal LAIVs are presented as options for yearly vaccination against influenza, FluMist was pulled off of the United States market from 2016 to 2018 due to its inefficiency against a common influenza strain in children. Since then, FluMist has been reformulated and has re-entered the market.[17]

 
Fluenz Tetra

The active ingredients in nasal LAIVs are grown in fertilized chicken eggs. The practice of growing viruses in chicken eggs is common in vaccine production because these viruses need to be grown inside cells.[18] Virus fluid from the incubated chicken eggs is extracted and killed for the viral antigen to be purified for LAIV production.[19] Similar to other vaccines, nasal LAIVs contain ingredients in addition to the viral antigen. Stabilizers such as gelatine, arginine hydrochloride, monosodium glutamate, and sucrose are commonly used in vaccines to assure the vaccines are still effective during and after production, transportation, and storage as well as delivery.[20][21] Stabilizers are especially important for nasal vaccines as proteases and amino-peptidase in the mucosal membrane can degrade proteins and peptides in vaccines.[4] Research continues to improve nasal LAIVs as influenza affects nearly 9 million people.[22] As influenza changes slightly each year, continuous research on new strains can improve vaccine efficiency. Research on nasal vaccine development for nontypeable Haemophilus influenzae shows that the vaccine binding to surface proteins prevented biofilm formation. As a result, this vaccine can have the potential to treat ear infections caused by biofilm from influenza infection.[23] New components like α-galactosylceramide (α-GalCer) are also being researched to be used as nasal vaccines against influenza. Since α-GalCer induced immune responses when immunized with a replication-deficient live adenovirus, there is evidence that nasal LAIVs can be co-immunized with other treatments against influenza.[24]

Intranasal COVID-19 Vaccines edit

Prior to the 2020 global COVID-19 pandemic, animal studies in 2004 on African green monkeys tested a SARS-associated coronavirus (SARS-CoV) vaccine and showed that these monkeys did not emit the virus from their upper respiratory tract after being infected.[25] Since then, several intranasal COVID-19 vaccines have been developed with the onset of the COVID-19 pandemic. inCOVACC, Razi Cov Pars, Sputnik, and Convidicia are nasal COVID-19 vaccines that were developed throughout the world to improve vaccine availability and reduce the spread of COVID-19. [citation needed]

 
COVID-19

In August 2020, during the COVID-19 pandemic, studies in mice and monkeys demonstrated that protection from the new coronavirus might be obtained through the nasal route. Another study postulated that if a COVID-19 vaccine could be given by a spray in the nose, people might be able to vaccinate themselves.[26] Research about the main characteristics of nasal spray vaccines that can affect the efficiency of vaccine delivery for COVID-19 indicates that the spray cone angle can impact the delivery efficiency; droplet initial velocity and composition did not have as much of an impact on nasal vaccine efficiency as the spray cone angle.[27]

India and China approved inCOVACC and Convidecia, respectively, to be used as boosters for those who have already received at least two COVID-19 vaccine doses.[28] Although nasal COVID-19 vaccine research continues in the United States, lack of government funding could prevent this research from moving on to human trials to get approval for public administration.[29] Privately funded research for nasal COVID-19 vaccines is starting to reach clinical trials; a nasal COVID-19 vaccine by Blue Lake Biotechnology has started its Phase 1 clinical trials as of late February 2023. Scientists speculate that nasal vaccines might have an advantage over other types of vaccines because they provide immune defense at the site of administration.[30]

Applications to veterinary medicine edit

Species other than humans use nasal vaccines to prevent diseases. Intranasal vaccines are used on dogs for Bordetella bronchiseptica to prevent infectious tracheobronchitis (ITB). ITB, commonly known as kennel cough, typically spreads in highly populated environments such as kennels and dog shelters. Consistent vaccination against ITB using an intranasal vaccine can create an immune response to protect the vaccinated dog. Consistent vaccination against ITB using an intranasal vaccine can create an immune response to protect the vaccinated dog.[31]

 
Bordetella Bronchiseptica

Cattle receive nasal vaccines against diseases such as bovine herpesvirus 1, parainfluenza type 3, and bovine rhinotracheitis virus.[32][33] As all three of these viruses are related to respiratory infection, using an intranasal route can bring the vaccine directly to the respiratory system.

Recent discoveries indicate that rainbow trout have a previously unknown lymphoid structure in their nasal cavity. This structure allows them to have fast innate and adaptive responses to nasal vaccines.[34]

Research edit

 
Nasal spray

Current research is exploring new technologies and developments to improve nasal vaccine delivery methods. Particle size and characteristics have become a focus of research as smaller particles can travel more easily to reach the epithelial layer of the nasal cavity compared to larger particles. Nanoparticles and nanosystems are being researched to optimize nasal delivery. Coated nanoparticles are an area of focus due to their properties to induce immune effects. Glycol chitosan-coated nanoparticles induced more of an immune response compared to the other types of nanoparticles.[35] Nanocarriers designed based on the characteristics of the nasal epithelium can be used to deliver nasal vaccines and can therefore make nasal vaccination more accessible.[36] Polymeric nanosystems are also being developed to deliver vaccines to target sites while preventing them from degrading; current research is focused on understanding the material and physical properties of biodegradable materials to be used in nanosystems to improve vaccine efficacy.[37] Research on the movement of nasal vaccine particles is focused on developing more effective ways for these vaccines to enter the body. An animal study on mice tested how a nasal vaccine can bypass issues with entry into the nasal epithelium by taking advantage of ciliary movement. The results indicated that tubulin tyrosine ligase-like family member 1 (Ttll1) knockout mice had higher levels of the vaccine antigen compared to the hetero mice.[38]

See also edit

References edit

  1. ^ Scherließ, Regina (2014). "15. Nasal administration of vaccines". In Foged, Camilla; Rades, Thomas; Perrie, Yvonne; Hook, Sarah (eds.). Subunit Vaccine Delivery. Springer. pp. 287–306. ISBN 978-1-4939-1417-3.
  2. ^ Boylston, Arthur (July 2012). "The origins of inoculation". Journal of the Royal Society of Medicine. 105 (7): 309–313. doi:10.1258/jrsm.2012.12k044. ISSN 0141-0768. PMC 3407399. PMID 22843649.
  3. ^ a b Rudenko, Larisa; Yeolekar, Leena; Kiseleva, Irina; Isakova-Sivak, Irina (October 2016). "Development and approval of live attenuated influenza vaccines based on Russian master donor viruses: Process challenges and success stories". Vaccine. 34 (45): 5436–5441. doi:10.1016/j.vaccine.2016.08.018. PMC 5357706. PMID 27593158.
  4. ^ a b c d Ramvikas, M.; Arumugam, M.; Chakrabarti, S.R.; Jaganathan, K.S. (2017), "Nasal Vaccine Delivery", Micro and Nanotechnology in Vaccine Development, Elsevier, pp. 279–301, doi:10.1016/b978-0-323-39981-4.00015-4, ISBN 978-0-323-39981-4, PMC 7151830
  5. ^ a b c Zhang, Jianfeng; Jex, Edward; Feng, Tsungwei; Sivko, Gloria S.; Baillie, Leslie W.; Goldman, Stanley; Van Kampen, Kent R.; Tang, De-chu C. (January 2013). "An Adenovirus-Vectored Nasal Vaccine Confers Rapid and Sustained Protection against Anthrax in a Single-Dose Regimen". Clinical and Vaccine Immunology. 20 (1): 1–8. doi:10.1128/CVI.00280-12. ISSN 1556-6811. PMC 3535766. PMID 23100479.
  6. ^ Kenigsberg, Ben (September 8, 2022). "The Anthrax Attacks' Review: Strange Behavior and an Incriminating Flask". The New York Times.
  7. ^ Nordqvist, Christian (December 23, 2022). "What to know about the anthrax vaccine". MedicalNewsToday.
  8. ^ a b c d Yusuf, Helmy; Kett, Vicky (2017-01-02). "Current prospects and future challenges for nasal vaccine delivery". Human Vaccines & Immunotherapeutics. 13 (1): 34–45. doi:10.1080/21645515.2016.1239668. ISSN 2164-5515. PMC 5287317. PMID 27936348.
  9. ^ Gras-Cabrerizo, Juan R.; García-Garrigós, Elena; Montserrat-Gili, Joan R.; Gras-Albert, Juan R.; Mirapeix-Lucas, Rosa; Massegur-Solench, Humbert; Quer-Agusti, Miquel (2018-03-01). "Anatomical Correlation Between Nasal Vascularisation and the Design of the Endonasal Pedicle Flaps". Indian Journal of Otolaryngology and Head & Neck Surgery. 70 (1): 167–173. doi:10.1007/s12070-017-1197-z. ISSN 0973-7707. PMC 5807293. PMID 29456964.
  10. ^ Davis, S. S. (2001-09-23). "Nasal vaccines". Advanced Drug Delivery Reviews. Nasal Vaccines. 51 (1): 21–42. doi:10.1016/S0169-409X(01)00162-4. ISSN 0169-409X. PMID 11516777.
  11. ^ Moakes, Richard J. A.; Davies, Scott P.; Stamataki, Zania; Grover, Liam M. (July 2021). "Formulation of a Composite Nasal Spray Enabling Enhanced Surface Coverage and Prophylaxis of SARS‐COV‐2". Advanced Materials. 33 (26): 2008304. Bibcode:2021AdM....3308304M. doi:10.1002/adma.202008304. ISSN 0935-9648. PMC 8212080. PMID 34060150.
  12. ^ "How do vaccines work?". World Health Organization. December 8, 2020.
  13. ^ Nian, Xuanxuan; Zhang, Jiayou; Huang, Shihe; Duan, Kai; Li, Xinguo; Yang, Xiaoming (2022-09-20). "Development of Nasal Vaccines and the Associated Challenges". Pharmaceutics. 14 (10): 1983. doi:10.3390/pharmaceutics14101983. ISSN 1999-4923. PMC 9609876. PMID 36297419.
  14. ^ a b "Nasal administration", Wikipedia, 2023-03-18, retrieved 2023-04-14
  15. ^ Research, Center for Biologics Evaluation and (2023-02-08). "FluMist Quadrivalent". FDA.
  16. ^ "Live Attenuated Influenza Vaccine [LAIV] (The Nasal Spray Flu Vaccine) | CDC". www.cdc.gov. 2022-08-25. Retrieved 2023-04-14.
  17. ^ Fox, Maggie (February 21, 2018). "FluMist nasal flu vaccine can come back, vaccine advisers say". NBC News.
  18. ^ Walmsley, Hannah (April 21, 2017). "What Does a Chicken Egg Have to Do with Your Flu Shot?". ABC Radio Canberra.
  19. ^ "How Influenza (Flu) Vaccines Are Made | CDC". www.cdc.gov. 2022-11-03. Retrieved 2023-04-14.
  20. ^ "Flu vaccine (Nasal)". vk.ovg.ox.ac.uk. Retrieved 2023-04-14.
  21. ^ Philadelphia, The Children's Hospital of. "Vaccine Education Center". www.chop.edu. Retrieved 2023-04-14.
  22. ^ CDC (2023-04-14). "Preliminary In-Season 2021-2022 Flu Burden Estimates". Centers for Disease Control and Prevention. Retrieved 2023-04-14.
  23. ^ Nakahashi-Ouchida, Rika; Mori, Hiromi; Yuki, Yoshikazu; Umemoto, Shingo; Hirano, Takashi; Uchida, Yohei; Machita, Tomonori; Yamanoue, Tomoyuki; Sawada, Shin-ichi; Suzuki, Masashi; Fujihashi, Kohtaro; Akiyoshi, Kazunari; Kurono, Yuichi; Kiyono, Hiroshi (2022-07-06). "Induction of Mucosal IgA–Mediated Protective Immunity Against Nontypeable Haemophilus influenzae Infection by a Cationic Nanogel–Based P6 Nasal Vaccine". Frontiers in Immunology. 13: 819859. doi:10.3389/fimmu.2022.819859. ISSN 1664-3224. PMC 9299436. PMID 35874779.
  24. ^ Ko, Sung-Youl; Ko, Hyun-Jeong; Chang, Woo-Sung; Park, Se-Ho; Kweon, Mi-Na; Kang, Chang-Yuil (2005-09-01). "α-Galactosylceramide Can Act As a Nasal Vaccine Adjuvant Inducing Protective Immune Responses against Viral Infection and Tumor". The Journal of Immunology. 175 (5): 3309–3317. doi:10.4049/jimmunol.175.5.3309. ISSN 0022-1767. PMID 16116223. S2CID 44270805.
  25. ^ Tabor, Edward (2007). Emerging viruses in human populations (1st ed.). Amsterdam: Elsevier. p. 68. ISBN 978-0-08-046790-0. OCLC 86106570.
  26. ^ "COVID research updates: Immune responses to coronavirus persist beyond 6 months". Nature. 20 November 2020. doi:10.1038/d41586-020-00502-w. PMID 32221507.
  27. ^ Hayati, Hamideh; Feng, Yu; Chen, Xiaole; Kolewe, Emily; Fromen, Catherine (2023-01-19). "Prediction of transport, deposition, and resultant immune response of nasal spray vaccine droplets using a CFPD—HCD model in a 6-year-old upper airway geometry to potentially prevent COVID-19". Experimental and Computational Multiphase Flow. 5 (3): 272–289. doi:10.1007/s42757-022-0145-7. ISSN 2661-8877. PMC 9851113. PMID 36694695.
  28. ^ "Two inhaled covid vaccines have been approved—but we don't know yet how good they are". MIT Technology Review. Retrieved 2023-04-14.
  29. ^ "Why the U.S. Doesn't Have a Nasal Vaccine for COVID-19". Time. 2022-10-31. Retrieved 2023-04-14.
  30. ^ "Nasal Covid vaccine shows promise in early clinical trial". NBC News. 24 February 2023. Retrieved 2023-04-14.
  31. ^ Ford, Richard B (2010). Textbook of veterinary internal medicine : diseases of the dog and the cat. Stephen J. Ettinger, Edward C. Feldman (7th ed.). St. Louis, Mo.: Elsevier Saunders. p. 857. ISBN 978-1-4160-6593-7. OCLC 428770833.{{cite book}}: CS1 maint: date and year (link)
  32. ^ Yates, W. D.; Kingscote, B. F.; Bradley, J. A.; Mitchell, D. (July 1983). "The relationship of serology and nasal microbiology to pulmonary lesions in feedlot cattle". Canadian Journal of Comparative Medicine. 47 (3): 375–378. ISSN 0008-4050. PMC 1235957. PMID 6315201.
  33. ^ "BOVILIS® NASALGEN®". Merck Animal Health USA. Retrieved 2023-04-14.
  34. ^ Salinas, Irene; Garcia, Benjamin; Dong, Fen; Casadei, Elisa (2022-05-01). "Discovery of an organized nasopharynx-associated lymphoid tissue in the nasal cavity of rainbow trout and its role in secondary adaptive immune responses to nasal vaccines". The Journal of Immunology. 208 (1_Supplement): 124.19. doi:10.4049/jimmunol.208.supp.124.19. ISSN 0022-1767. S2CID 255719637.
  35. ^ Pawar, Dilip; Mangal, Sharad; Goswami, Roshan; Jaganathan, K. S. (2013-11-01). "Development and characterization of surface modified PLGA nanoparticles for nasal vaccine delivery: Effect of mucoadhesive coating on antigen uptake and immune adjuvant activity". European Journal of Pharmaceutics and Biopharmaceutics. 85 (3, Part A): 550–559. doi:10.1016/j.ejpb.2013.06.017. ISSN 0939-6411. PMID 23831265.
  36. ^ Csaba, Noemi; Garcia-Fuentes, Marcos; Alonso, Maria Jose (2009-02-27). "Nanoparticles for nasal vaccination". Advanced Drug Delivery Reviews. 61 (2): 140–157. doi:10.1016/j.addr.2008.09.005. ISSN 0169-409X. PMID 19121350.
  37. ^ Köping-Höggård, Magnus; Sánchez, Alejandro; Alonso, María José (2005-04-01). "Nanoparticles as carriers for nasal vaccine delivery". Expert Review of Vaccines. 4 (2): 185–196. doi:10.1586/14760584.4.2.185. ISSN 1476-0584. PMID 15889992. S2CID 20471116.
  38. ^ Lan, Huangwenxian; Suzuki, Hidehiko; Nagatake, Takahiro; Hosomi, Koji; Ikegami, Koji; Setou, Mitsutoshi; Kunisawa, Jun (August 2020). "Impaired mucociliary motility enhances antigen-specific nasal IgA immune responses to a cholera toxin-based nasal vaccine". International Immunology. 32 (8): 559–568. doi:10.1093/intimm/dxaa029. PMC 9262165. PMID 32347929. Retrieved 2023-04-14.

January 01, 1970
nasal, vaccine, nasal, vaccine, vaccine, administered, through, nose, that, stimulates, immune, response, without, injection, induces, immunity, through, inner, surface, nose, surface, that, naturally, comes, contact, with, many, airborne, microbes, emerging, . A nasal vaccine is a vaccine administered through the nose that stimulates an immune response without an injection It induces immunity through the inner surface of the nose a surface that naturally comes in contact with many airborne microbes 1 Nasal vaccines are emerging as an alternative to injectable vaccines because they do not use needles and can be introduced through the mucosal route Nasal vaccines can be delivered through nasal sprays to prevent respiratory infections such as influenza Contents 1 History 2 Administration 3 Live attenuated influenza vaccine 4 Intranasal COVID 19 Vaccines 5 Applications to veterinary medicine 6 Research 7 See also 8 ReferencesHistory editNasal inoculation dates as far back as the 17th century in China during the Kangxi Emperor s reign Documentation during this period indicates that the Kangxi Emperor vaccinated his family army and others for mild smallpox Manuals detailing vaccination techniques at the time all focused on sending smallpox up the nose of the individual being vaccinated Although other vaccination techniques were developed using an infected individual s scabs a common method was to place a cotton swab with the fluid from an infected person s pustule up the nose 2 Following smallpox influenza became a prominent focus for nasal vaccine development The first live attenuated influenza vaccine LAIV in the form of a nasal spray was created in Russia by the Institute of Experimental Medicine in 1987 This nasal vaccine development was based on the Russian backbone of LAIV while nasal vaccines since then have been based on other LAIV backbones 3 The first nasal influenza vaccine was released in the United States in 2001 but was taken off the market due to toxicity concerns FluMist one of the most prominent nasal LAIVs was released in 2003 as nasal LAIVs continued developing 4 Nasal vaccine nbsp Application of an intranasal mist of the flu vaccineSpecialtyVaccine delivery edit on Wikidata Anthrax attacks at the beginning of the 21st century caused a demand for nasal vaccine development As anthrax is an airborne substance that can be inhaled a nasal vaccine has the potential to be used to protect individuals from the effects it can have on the respiratory system 5 Following the September 11 2001 terrorist attacks in the United States several individuals at news stations and U S senators died after being sent letters with anthrax as an act of bioterrorism 6 Nasal vaccine research and development against anthrax was encouraged by the U S government in an effort to vaccinate troops 5 7 BioThrax the current anthrax vaccine that is licensed and administered in the United States requires up to five intramuscular injections and annual boosters research within the past decade has developed an alternative nasal vaccine that follows the path of infection for anthrax and induces both humoral and cellular immune responses 5 The global COVID 19 pandemic led to a rise in nasal vaccines against coronavirus International efforts for vaccine development occurred as countries such as India Iran Russia and China created nasal COVID 19 vaccines citation needed Administration editNasal vaccines are a subsection of mucosal immunization as they use a mucosal route for vaccine delivery As many pathogens can enter the body through the nose nasal vaccines take advantage of this mechanism to deliver the vaccine The nose has multiple lines of defense to prevent pathogens from entering further into the body Nasal hairs are the first defense as they are at the entrance of the nose and prevent large particles from entering The mucus layer in the nasal cavity can trap smaller particles that get past the nose hairs 8 The nasal cavity has a large vascularization network so particles can go through the epithelial layer and directly enter the bloodstream 9 Intruding particles will interact with the mucosal immune system if they reach the nasal mucosa The mucosal immune system is composed of lymphoid tissue B cells T cells and antigen presenting cells These different types of cells work together to identify intruding particles and trigger an immune response 8 Nasal vaccines must overcome these barriers and get clearance to deliver the viral antigen to patients 4 Nasal vaccines must overcome these barriers and get clearance to deliver the viral antigen to patients 10 Nasal vaccines can come in different forms such as solutions liquids powders gels and solid inserts The most prevalent type of nasal vaccine in research and clinical application is solutions due to its ease of use Although solutions are usually pipetted into test subjects nostrils when conducting animal trials for nasal vaccines nasal sprays are considered the most practical approach for mass human vaccination using nasal vaccines 8 A nasal spray is able to bypass the initial layers of the nasal mucosa and deliver the vaccine particles directly to the mucoadhesive layer 11 The antigen in the nasal vaccine can then trigger an immune response and prevent infection due to nasal vaccines accessibility to the immune system 12 13 nbsp Human Nasal Anatomy Nasal sprays are commonly used for delivering drugs in addition to vaccines Decongestant drugs are often directly delivered to the nose through nasal sprays Cold and allergy medication can be administered using nasal sprays for local delivery by bypassing nasal hairs and being introduced to the nasal cavity Intranasal administration can have less drug degradation compared to oral administration because of direct particle delivery Peptide drugs used for hormone treatments can be delivered nasally through nasal sprays instead of orally to retain particle integrity Nasal sprays can also be used to deliver diabetes treatment steroids and intranasal oxytocin to induce labor Nasal administration is also used to deliver anesthetics and sedatives due to direct access to the mucosal immune system and bloodstream 14 The olfactory epithelium makes up approximately 7 of the surface area of the nasal cavity and is connected to the olfactory bulb in the brain Drugs and vaccines can be delivered to the brain past the blood brain barrier through olfactory nerve cells 14 Compared to injectable vaccines nasal vaccines can be advantageous because they are safe painless and easy to use Nasal vaccines do not require a needle which eliminates pain from needlestick injuries and safety concerns due to cross contamination and needle disposal Some studies also show that intranasal vaccines can generate cross reactive antibodies that could lead to cross protection 8 Live attenuated influenza vaccine editMain article Live attenuated influenza vaccineThe live attenuated influenza vaccine LAIV in the form of a nasal spray was one of the first nasal vaccines released on the market Nasal spray LAIVs have been used since the late 1980s as an alternative to the injectable influenza vaccine 3 Nasal influenza vaccines have become popular as they reduce the risk of intramuscular injuries from administration and are painless They can also be given more easily to patients because they do not require a needle nbsp FluMist QuadrivalentThe most prominent nasal LAIV is FluMist which was released in 2003 4 FluMist officially known as FluMist Quadrivalent in the United States and Fluenz in Europe is known to be the only flu vaccine on the market that does not use a needle 15 All nasal LAIVs for recent flu seasons 2022 2023 are considered quadrivalents because they are designed to protect against four types of flu viruses an influenza A H1N1 virus an influenza A H3N2 virus and two influenza B viruses 16 Although injectable and nasal LAIVs are presented as options for yearly vaccination against influenza FluMist was pulled off of the United States market from 2016 to 2018 due to its inefficiency against a common influenza strain in children Since then FluMist has been reformulated and has re entered the market 17 nbsp Fluenz TetraThe active ingredients in nasal LAIVs are grown in fertilized chicken eggs The practice of growing viruses in chicken eggs is common in vaccine production because these viruses need to be grown inside cells 18 Virus fluid from the incubated chicken eggs is extracted and killed for the viral antigen to be purified for LAIV production 19 Similar to other vaccines nasal LAIVs contain ingredients in addition to the viral antigen Stabilizers such as gelatine arginine hydrochloride monosodium glutamate and sucrose are commonly used in vaccines to assure the vaccines are still effective during and after production transportation and storage as well as delivery 20 21 Stabilizers are especially important for nasal vaccines as proteases and amino peptidase in the mucosal membrane can degrade proteins and peptides in vaccines 4 Research continues to improve nasal LAIVs as influenza affects nearly 9 million people 22 As influenza changes slightly each year continuous research on new strains can improve vaccine efficiency Research on nasal vaccine development for nontypeable Haemophilus influenzae shows that the vaccine binding to surface proteins prevented biofilm formation As a result this vaccine can have the potential to treat ear infections caused by biofilm from influenza infection 23 New components like a galactosylceramide a GalCer are also being researched to be used as nasal vaccines against influenza Since a GalCer induced immune responses when immunized with a replication deficient live adenovirus there is evidence that nasal LAIVs can be co immunized with other treatments against influenza 24 Intranasal COVID 19 Vaccines editPrior to the 2020 global COVID 19 pandemic animal studies in 2004 on African green monkeys tested a SARS associated coronavirus SARS CoV vaccine and showed that these monkeys did not emit the virus from their upper respiratory tract after being infected 25 Since then several intranasal COVID 19 vaccines have been developed with the onset of the COVID 19 pandemic inCOVACC Razi Cov Pars Sputnik and Convidicia are nasal COVID 19 vaccines that were developed throughout the world to improve vaccine availability and reduce the spread of COVID 19 citation needed nbsp COVID 19 In August 2020 during the COVID 19 pandemic studies in mice and monkeys demonstrated that protection from the new coronavirus might be obtained through the nasal route Another study postulated that if a COVID 19 vaccine could be given by a spray in the nose people might be able to vaccinate themselves 26 Research about the main characteristics of nasal spray vaccines that can affect the efficiency of vaccine delivery for COVID 19 indicates that the spray cone angle can impact the delivery efficiency droplet initial velocity and composition did not have as much of an impact on nasal vaccine efficiency as the spray cone angle 27 India and China approved inCOVACC and Convidecia respectively to be used as boosters for those who have already received at least two COVID 19 vaccine doses 28 Although nasal COVID 19 vaccine research continues in the United States lack of government funding could prevent this research from moving on to human trials to get approval for public administration 29 Privately funded research for nasal COVID 19 vaccines is starting to reach clinical trials a nasal COVID 19 vaccine by Blue Lake Biotechnology has started its Phase 1 clinical trials as of late February 2023 Scientists speculate that nasal vaccines might have an advantage over other types of vaccines because they provide immune defense at the site of administration 30 Applications to veterinary medicine editSpecies other than humans use nasal vaccines to prevent diseases Intranasal vaccines are used on dogs for Bordetella bronchiseptica to prevent infectious tracheobronchitis ITB ITB commonly known as kennel cough typically spreads in highly populated environments such as kennels and dog shelters Consistent vaccination against ITB using an intranasal vaccine can create an immune response to protect the vaccinated dog Consistent vaccination against ITB using an intranasal vaccine can create an immune response to protect the vaccinated dog 31 nbsp Bordetella Bronchiseptica Cattle receive nasal vaccines against diseases such as bovine herpesvirus 1 parainfluenza type 3 and bovine rhinotracheitis virus 32 33 As all three of these viruses are related to respiratory infection using an intranasal route can bring the vaccine directly to the respiratory system Recent discoveries indicate that rainbow trout have a previously unknown lymphoid structure in their nasal cavity This structure allows them to have fast innate and adaptive responses to nasal vaccines 34 Research edit nbsp Nasal spray Current research is exploring new technologies and developments to improve nasal vaccine delivery methods Particle size and characteristics have become a focus of research as smaller particles can travel more easily to reach the epithelial layer of the nasal cavity compared to larger particles Nanoparticles and nanosystems are being researched to optimize nasal delivery Coated nanoparticles are an area of focus due to their properties to induce immune effects Glycol chitosan coated nanoparticles induced more of an immune response compared to the other types of nanoparticles 35 Nanocarriers designed based on the characteristics of the nasal epithelium can be used to deliver nasal vaccines and can therefore make nasal vaccination more accessible 36 Polymeric nanosystems are also being developed to deliver vaccines to target sites while preventing them from degrading current research is focused on understanding the material and physical properties of biodegradable materials to be used in nanosystems to improve vaccine efficacy 37 Research on the movement of nasal vaccine particles is focused on developing more effective ways for these vaccines to enter the body An animal study on mice tested how a nasal vaccine can bypass issues with entry into the nasal epithelium by taking advantage of ciliary movement The results indicated that tubulin tyrosine ligase like family member 1 Ttll1 knockout mice had higher levels of the vaccine antigen compared to the hetero mice 38 See also editNasal administration Mucosal immunologyReferences edit Scherliess Regina 2014 15 Nasal administration of vaccines In Foged Camilla Rades Thomas Perrie Yvonne Hook Sarah eds Subunit Vaccine Delivery Springer pp 287 306 ISBN 978 1 4939 1417 3 Boylston Arthur July 2012 The origins of inoculation Journal of the Royal Society of Medicine 105 7 309 313 doi 10 1258 jrsm 2012 12k044 ISSN 0141 0768 PMC 3407399 PMID 22843649 a b Rudenko Larisa Yeolekar Leena Kiseleva Irina Isakova Sivak Irina October 2016 Development and approval of live attenuated influenza vaccines based on Russian master donor viruses Process challenges and success stories Vaccine 34 45 5436 5441 doi 10 1016 j vaccine 2016 08 018 PMC 5357706 PMID 27593158 a b c d Ramvikas M Arumugam M Chakrabarti S R Jaganathan K S 2017 Nasal Vaccine Delivery Micro and Nanotechnology in Vaccine Development Elsevier pp 279 301 doi 10 1016 b978 0 323 39981 4 00015 4 ISBN 978 0 323 39981 4 PMC 7151830 a b c Zhang Jianfeng Jex Edward Feng Tsungwei Sivko Gloria S Baillie Leslie W Goldman Stanley Van Kampen Kent R Tang De chu C January 2013 An Adenovirus Vectored Nasal Vaccine Confers Rapid and Sustained Protection against Anthrax in a Single Dose Regimen Clinical and Vaccine Immunology 20 1 1 8 doi 10 1128 CVI 00280 12 ISSN 1556 6811 PMC 3535766 PMID 23100479 Kenigsberg Ben September 8 2022 The Anthrax Attacks Review Strange Behavior and an Incriminating Flask The New York Times Nordqvist Christian December 23 2022 What to know about the anthrax vaccine MedicalNewsToday a b c d Yusuf Helmy Kett Vicky 2017 01 02 Current prospects and future challenges for nasal vaccine delivery Human Vaccines amp Immunotherapeutics 13 1 34 45 doi 10 1080 21645515 2016 1239668 ISSN 2164 5515 PMC 5287317 PMID 27936348 Gras Cabrerizo Juan R Garcia Garrigos Elena Montserrat Gili Joan R Gras Albert Juan R Mirapeix Lucas Rosa Massegur Solench Humbert Quer Agusti Miquel 2018 03 01 Anatomical Correlation Between Nasal Vascularisation and the Design of the Endonasal Pedicle Flaps Indian Journal of Otolaryngology and Head amp Neck Surgery 70 1 167 173 doi 10 1007 s12070 017 1197 z ISSN 0973 7707 PMC 5807293 PMID 29456964 Davis S S 2001 09 23 Nasal vaccines Advanced Drug Delivery Reviews Nasal Vaccines 51 1 21 42 doi 10 1016 S0169 409X 01 00162 4 ISSN 0169 409X PMID 11516777 Moakes Richard J A Davies Scott P Stamataki Zania Grover Liam M July 2021 Formulation of a Composite Nasal Spray Enabling Enhanced Surface Coverage and Prophylaxis of SARS COV 2 Advanced Materials 33 26 2008304 Bibcode 2021AdM 3308304M doi 10 1002 adma 202008304 ISSN 0935 9648 PMC 8212080 PMID 34060150 How do vaccines work World Health Organization December 8 2020 Nian Xuanxuan Zhang Jiayou Huang Shihe Duan Kai Li Xinguo Yang Xiaoming 2022 09 20 Development of Nasal Vaccines and the Associated Challenges Pharmaceutics 14 10 1983 doi 10 3390 pharmaceutics14101983 ISSN 1999 4923 PMC 9609876 PMID 36297419 a b Nasal administration Wikipedia 2023 03 18 retrieved 2023 04 14 Research Center for Biologics Evaluation and 2023 02 08 FluMist Quadrivalent FDA Live Attenuated Influenza Vaccine LAIV The Nasal Spray Flu Vaccine CDC www cdc gov 2022 08 25 Retrieved 2023 04 14 Fox Maggie February 21 2018 FluMist nasal flu vaccine can come back vaccine advisers say NBC News Walmsley Hannah April 21 2017 What Does a Chicken Egg Have to Do with Your Flu Shot ABC Radio Canberra How Influenza Flu Vaccines Are Made CDC www cdc gov 2022 11 03 Retrieved 2023 04 14 Flu vaccine Nasal vk ovg ox ac uk Retrieved 2023 04 14 Philadelphia The Children s Hospital of Vaccine Education Center www chop edu Retrieved 2023 04 14 CDC 2023 04 14 Preliminary In Season 2021 2022 Flu Burden Estimates Centers for Disease Control and Prevention Retrieved 2023 04 14 Nakahashi Ouchida Rika Mori Hiromi Yuki Yoshikazu Umemoto Shingo Hirano Takashi Uchida Yohei Machita Tomonori Yamanoue Tomoyuki Sawada Shin ichi Suzuki Masashi Fujihashi Kohtaro Akiyoshi Kazunari Kurono Yuichi Kiyono Hiroshi 2022 07 06 Induction of Mucosal IgA Mediated Protective Immunity Against Nontypeable Haemophilus influenzae Infection by a Cationic Nanogel Based P6 Nasal Vaccine Frontiers in Immunology 13 819859 doi 10 3389 fimmu 2022 819859 ISSN 1664 3224 PMC 9299436 PMID 35874779 Ko Sung Youl Ko Hyun Jeong Chang Woo Sung Park Se Ho Kweon Mi Na Kang Chang Yuil 2005 09 01 a Galactosylceramide Can Act As a Nasal Vaccine Adjuvant Inducing Protective Immune Responses against Viral Infection and Tumor The Journal of Immunology 175 5 3309 3317 doi 10 4049 jimmunol 175 5 3309 ISSN 0022 1767 PMID 16116223 S2CID 44270805 Tabor Edward 2007 Emerging viruses in human populations 1st ed Amsterdam Elsevier p 68 ISBN 978 0 08 046790 0 OCLC 86106570 COVID research updates Immune responses to coronavirus persist beyond 6 months Nature 20 November 2020 doi 10 1038 d41586 020 00502 w PMID 32221507 Hayati Hamideh Feng Yu Chen Xiaole Kolewe Emily Fromen Catherine 2023 01 19 Prediction of transport deposition and resultant immune response of nasal spray vaccine droplets using a CFPD HCD model in a 6 year old upper airway geometry to potentially prevent COVID 19 Experimental and Computational Multiphase Flow 5 3 272 289 doi 10 1007 s42757 022 0145 7 ISSN 2661 8877 PMC 9851113 PMID 36694695 Two inhaled covid vaccines have been approved but we don t know yet how good they are MIT Technology Review Retrieved 2023 04 14 Why the U S Doesn t Have a Nasal Vaccine for COVID 19 Time 2022 10 31 Retrieved 2023 04 14 Nasal Covid vaccine shows promise in early clinical trial NBC News 24 February 2023 Retrieved 2023 04 14 Ford Richard B 2010 Textbook of veterinary internal medicine diseases of the dog and the cat Stephen J Ettinger Edward C Feldman 7th ed St Louis Mo Elsevier Saunders p 857 ISBN 978 1 4160 6593 7 OCLC 428770833 a href Template Cite book html title Template Cite book cite book a CS1 maint date and year link Yates W D Kingscote B F Bradley J A Mitchell D July 1983 The relationship of serology and nasal microbiology to pulmonary lesions in feedlot cattle Canadian Journal of Comparative Medicine 47 3 375 378 ISSN 0008 4050 PMC 1235957 PMID 6315201 BOVILIS NASALGEN Merck Animal Health USA Retrieved 2023 04 14 Salinas Irene Garcia Benjamin Dong Fen Casadei Elisa 2022 05 01 Discovery of an organized nasopharynx associated lymphoid tissue in the nasal cavity of rainbow trout and its role in secondary adaptive immune responses to nasal vaccines The Journal of Immunology 208 1 Supplement 124 19 doi 10 4049 jimmunol 208 supp 124 19 ISSN 0022 1767 S2CID 255719637 Pawar Dilip Mangal Sharad Goswami Roshan Jaganathan K S 2013 11 01 Development and characterization of surface modified PLGA nanoparticles for nasal vaccine delivery Effect of mucoadhesive coating on antigen uptake and immune adjuvant activity European Journal of Pharmaceutics and Biopharmaceutics 85 3 Part A 550 559 doi 10 1016 j ejpb 2013 06 017 ISSN 0939 6411 PMID 23831265 Csaba Noemi Garcia Fuentes Marcos Alonso Maria Jose 2009 02 27 Nanoparticles for nasal vaccination Advanced Drug Delivery Reviews 61 2 140 157 doi 10 1016 j addr 2008 09 005 ISSN 0169 409X PMID 19121350 Koping Hoggard Magnus Sanchez Alejandro Alonso Maria Jose 2005 04 01 Nanoparticles as carriers for nasal vaccine delivery Expert Review of Vaccines 4 2 185 196 doi 10 1586 14760584 4 2 185 ISSN 1476 0584 PMID 15889992 S2CID 20471116 Lan Huangwenxian Suzuki Hidehiko Nagatake Takahiro Hosomi Koji Ikegami Koji Setou Mitsutoshi Kunisawa Jun August 2020 Impaired mucociliary motility enhances antigen specific nasal IgA immune responses to a cholera toxin based nasal vaccine International Immunology 32 8 559 568 doi 10 1093 intimm dxaa029 PMC 9262165 PMID 32347929 Retrieved 2023 04 14 Retrieved from https en wikipedia org w index php title Nasal vaccine amp oldid 1177799305, wikipedia, wiki, book, books, library,

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