Percutaneous Vaccination as an Effective Method of Delivery of MVA and MVA-Vectored Vaccines.
Identifieur interne : 000353 ( PubMed/Checkpoint ); précédent : 000352; suivant : 000354Percutaneous Vaccination as an Effective Method of Delivery of MVA and MVA-Vectored Vaccines.
Auteurs : Clement A. Meseda [États-Unis] ; Vajini Atukorale [États-Unis] ; Jordan Kuhn [États-Unis] ; Falko Schmeisser [États-Unis] ; Jerry P. Weir [États-Unis]Source :
- PloS one [ 1932-6203 ] ; 2016.
Descripteurs français
- KwdFr :
- Animaux, Anticorps antiviraux (immunologie), Anticorps neutralisants (immunologie), Cytokines (métabolisme), Herpèsvirus humain de type 2 (immunologie), Immunoglobuline G (immunologie), Modèles animaux de maladie humaine, Souris, Sous-type H5N1 du virus de la grippe A (immunologie), Vaccination, Vaccine (), Vaccine (métabolisme), Vaccins antiviraux (administration et posologie), Vaccins antiviraux (génétique), Vaccins contre les virus herpès simplex (administration et posologie), Vecteurs génétiques (administration et posologie), Vecteurs génétiques (génétique), Virus de la vaccine (génétique), Virus de la vaccine (immunologie).
- MESH :
- administration et posologie : Vaccins antiviraux, Vaccins contre les virus herpès simplex, Vecteurs génétiques.
- génétique : Vaccins antiviraux, Vecteurs génétiques, Virus de la vaccine.
- immunologie : Anticorps antiviraux, Anticorps neutralisants, Herpèsvirus humain de type 2, Immunoglobuline G, Sous-type H5N1 du virus de la grippe A, Virus de la vaccine.
- métabolisme : Cytokines, Vaccine.
- Animaux, Modèles animaux de maladie humaine, Souris, Vaccination, Vaccine.
English descriptors
- KwdEn :
- Animals, Antibodies, Neutralizing (immunology), Antibodies, Viral (immunology), Cytokines (metabolism), Disease Models, Animal, Genetic Vectors (administration & dosage), Genetic Vectors (genetics), Herpes Simplex Virus Vaccines (administration & dosage), Herpesvirus 2, Human (immunology), Immunoglobulin G (immunology), Influenza A Virus, H5N1 Subtype (immunology), Mice, Vaccination, Vaccinia (metabolism), Vaccinia (prevention & control), Vaccinia virus (genetics), Vaccinia virus (immunology), Viral Vaccines (administration & dosage), Viral Vaccines (genetics).
- MESH :
- chemical , administration & dosage : Herpes Simplex Virus Vaccines, Viral Vaccines.
- chemical , genetics : Viral Vaccines.
- chemical , immunology : Antibodies, Neutralizing, Antibodies, Viral, Immunoglobulin G.
- chemical , metabolism : Cytokines.
- administration & dosage : Genetic Vectors.
- genetics : Genetic Vectors, Vaccinia virus.
- immunology : Herpesvirus 2, Human, Influenza A Virus, H5N1 Subtype, Vaccinia virus.
- metabolism : Vaccinia.
- prevention & control : Vaccinia.
- Animals, Disease Models, Animal, Mice, Vaccination.
Abstract
The robustness of immune responses to an antigen could be dictated by the route of vaccine inoculation. Traditional smallpox vaccines, essentially vaccinia virus strains, that were used in the eradication of smallpox were administered by percutaneous inoculation (skin scarification). The modified vaccinia virus Ankara is licensed as a smallpox vaccine in Europe and Canada and currently undergoing clinical development in the United States. MVA is also being investigated as a vector for the delivery of heterologous genes for prophylactic or therapeutic immunization. Since MVA is replication-deficient, MVA and MVA-vectored vaccines are often inoculated through the intramuscular, intradermal or subcutaneous routes. Vaccine inoculation via the intramuscular, intradermal or subcutaneous routes requires the use of injection needles, and an estimated 10 to 20% of the population of the United States has needle phobia. Following an observation in our laboratory that a replication-deficient recombinant vaccinia virus derived from the New York City Board of Health strain elicited protective immune responses in a mouse model upon inoculation by tail scarification, we investigated whether MVA and MVA recombinants can elicit protective responses following percutaneous administration in mouse models. Our data suggest that MVA administered by percutaneous inoculation, elicited vaccinia-specific antibody responses, and protected mice from lethal vaccinia virus challenge, at levels comparable to or better than subcutaneous or intramuscular inoculation. High titers of specific neutralizing antibodies were elicited in mice inoculated with a recombinant MVA expressing the herpes simplex type 2 glycoprotein D after scarification. Similarly, a recombinant MVA expressing the hemagglutinin of attenuated influenza virus rgA/Viet Nam/1203/2004 (H5N1) elicited protective immune responses when administered at low doses by scarification. Taken together, our data suggest that MVA and MVA-vectored vaccines inoculated by scarification can elicit protective immune responses that are comparable to subcutaneous vaccination, and may allow for antigen sparing when vaccine supply is limited.
DOI: 10.1371/journal.pone.0149364
PubMed: 26895072
Affiliations:
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Traditional smallpox vaccines, essentially vaccinia virus strains, that were used in the eradication of smallpox were administered by percutaneous inoculation (skin scarification). The modified vaccinia virus Ankara is licensed as a smallpox vaccine in Europe and Canada and currently undergoing clinical development in the United States. MVA is also being investigated as a vector for the delivery of heterologous genes for prophylactic or therapeutic immunization. Since MVA is replication-deficient, MVA and MVA-vectored vaccines are often inoculated through the intramuscular, intradermal or subcutaneous routes. Vaccine inoculation via the intramuscular, intradermal or subcutaneous routes requires the use of injection needles, and an estimated 10 to 20% of the population of the United States has needle phobia. Following an observation in our laboratory that a replication-deficient recombinant vaccinia virus derived from the New York City Board of Health strain elicited protective immune responses in a mouse model upon inoculation by tail scarification, we investigated whether MVA and MVA recombinants can elicit protective responses following percutaneous administration in mouse models. Our data suggest that MVA administered by percutaneous inoculation, elicited vaccinia-specific antibody responses, and protected mice from lethal vaccinia virus challenge, at levels comparable to or better than subcutaneous or intramuscular inoculation. High titers of specific neutralizing antibodies were elicited in mice inoculated with a recombinant MVA expressing the herpes simplex type 2 glycoprotein D after scarification. Similarly, a recombinant MVA expressing the hemagglutinin of attenuated influenza virus rgA/Viet Nam/1203/2004 (H5N1) elicited protective immune responses when administered at low doses by scarification. Taken together, our data suggest that MVA and MVA-vectored vaccines inoculated by scarification can elicit protective immune responses that are comparable to subcutaneous vaccination, and may allow for antigen sparing when vaccine supply is limited. </div></front></TEI><pubmed><MedlineCitation Status="MEDLINE" Owner="NLM"><PMID Version="1">26895072</PMID><DateCompleted><Year>2016</Year><Month>08</Month><Day>02</Day></DateCompleted><DateRevised><Year>2019</Year><Month>02</Month><Day>22</Day></DateRevised><Article PubModel="Electronic-eCollection"><Journal><ISSN IssnType="Electronic">1932-6203</ISSN><JournalIssue CitedMedium="Internet"><Volume>11</Volume><Issue>2</Issue><PubDate><Year>2016</Year></PubDate></JournalIssue><Title>PloS one</Title><ISOAbbreviation>PLoS ONE</ISOAbbreviation></Journal><ArticleTitle>Percutaneous Vaccination as an Effective Method of Delivery of MVA and MVA-Vectored Vaccines.</ArticleTitle><Pagination><MedlinePgn>e0149364</MedlinePgn></Pagination><ELocationID EIdType="doi" ValidYN="Y">10.1371/journal.pone.0149364</ELocationID><Abstract><AbstractText>The robustness of immune responses to an antigen could be dictated by the route of vaccine inoculation. Traditional smallpox vaccines, essentially vaccinia virus strains, that were used in the eradication of smallpox were administered by percutaneous inoculation (skin scarification). The modified vaccinia virus Ankara is licensed as a smallpox vaccine in Europe and Canada and currently undergoing clinical development in the United States. MVA is also being investigated as a vector for the delivery of heterologous genes for prophylactic or therapeutic immunization. Since MVA is replication-deficient, MVA and MVA-vectored vaccines are often inoculated through the intramuscular, intradermal or subcutaneous routes. Vaccine inoculation via the intramuscular, intradermal or subcutaneous routes requires the use of injection needles, and an estimated 10 to 20% of the population of the United States has needle phobia. Following an observation in our laboratory that a replication-deficient recombinant vaccinia virus derived from the New York City Board of Health strain elicited protective immune responses in a mouse model upon inoculation by tail scarification, we investigated whether MVA and MVA recombinants can elicit protective responses following percutaneous administration in mouse models. Our data suggest that MVA administered by percutaneous inoculation, elicited vaccinia-specific antibody responses, and protected mice from lethal vaccinia virus challenge, at levels comparable to or better than subcutaneous or intramuscular inoculation. High titers of specific neutralizing antibodies were elicited in mice inoculated with a recombinant MVA expressing the herpes simplex type 2 glycoprotein D after scarification. Similarly, a recombinant MVA expressing the hemagglutinin of attenuated influenza virus rgA/Viet Nam/1203/2004 (H5N1) elicited protective immune responses when administered at low doses by scarification. Taken together, our data suggest that MVA and MVA-vectored vaccines inoculated by scarification can elicit protective immune responses that are comparable to subcutaneous vaccination, and may allow for antigen sparing when vaccine supply is limited. </AbstractText></Abstract><AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>Meseda</LastName><ForeName>Clement A</ForeName><Initials>CA</Initials><AffiliationInfo><Affiliation>Division of Viral Products, Center for Biologics Evaluation and Research, US Food & Drug Administration, 10903 New Hampshire Avenue, Silver Spring, Maryland, 20993, United States of America.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Atukorale</LastName><ForeName>Vajini</ForeName><Initials>V</Initials><AffiliationInfo><Affiliation>Division of Viral Products, Center for Biologics Evaluation and Research, US Food & Drug Administration, 10903 New Hampshire Avenue, Silver Spring, Maryland, 20993, United States of America.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Kuhn</LastName><ForeName>Jordan</ForeName><Initials>J</Initials><AffiliationInfo><Affiliation>Division of Viral Products, Center for Biologics Evaluation and Research, US Food & Drug Administration, 10903 New Hampshire Avenue, Silver Spring, Maryland, 20993, United States of America.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Schmeisser</LastName><ForeName>Falko</ForeName><Initials>F</Initials><AffiliationInfo><Affiliation>Division of Viral Products, Center for Biologics Evaluation and Research, US Food & Drug Administration, 10903 New Hampshire Avenue, Silver Spring, Maryland, 20993, United States of America.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Weir</LastName><ForeName>Jerry P</ForeName><Initials>JP</Initials><AffiliationInfo><Affiliation>Division of Viral Products, Center for Biologics Evaluation and Research, US Food & Drug Administration, 10903 New Hampshire Avenue, Silver Spring, Maryland, 20993, United States of America.</Affiliation></AffiliationInfo></Author></AuthorList><Language>eng</Language><PublicationTypeList><PublicationType UI="D016428">Journal Article</PublicationType><PublicationType UI="D013487">Research Support, U.S. Gov't, P.H.S.</PublicationType></PublicationTypeList><ArticleDate DateType="Electronic"><Year>2016</Year><Month>02</Month><Day>19</Day></ArticleDate></Article><MedlineJournalInfo><Country>United States</Country><MedlineTA>PLoS One</MedlineTA><NlmUniqueID>101285081</NlmUniqueID><ISSNLinking>1932-6203</ISSNLinking></MedlineJournalInfo><ChemicalList><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D057134">Antibodies, Neutralizing</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D000914">Antibodies, Viral</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance 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