Stability and pre-formulation development of a plant-produced anthrax vaccine candidate

Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the r...

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Published in	Vaccine Vol. 35; no. 41; pp. 5463 - 5470
Main Authors	Jones, R. Mark, Burke, Michael, Dubose, Devon, Chichester, Jessica A., Manceva, Slobodanka, Horsey, April, Streatfield, Stephen J., Breit, Jeff, Yusibov, Vidadi
Format	Journal Article
Language	English
Published	Netherlands Elsevier Ltd 04.10.2017 Elsevier Limited
Subjects	adverse effects Allergy and Immunology Ambient temperature Animals Anthrax Anthrax - immunology Anthrax Vaccines - blood Anthrax Vaccines - immunology Antibodies, Bacterial Antibodies, Neutralizing - immunology Antigens Antigens, Bacterial - immunology Bacillus anthracis - immunology Bacterial Toxins - immunology Biotechnology Chemistry, Pharmaceutical - methods Chromatography cold Drug Stability Drug Storage - methods Edema Formulations Immune response Immunization Immunization - methods Life cycle engineering Life cycle product development Life cycles Mice Mice, Inbred BALB C neutralization neutralizing antibodies Peptides Plant-produced Plants - chemistry Powder Powders - chemistry Product development Protective antigen Proteins Scanning electron microscopy Side effects Spray dry spray drying Stability storage storage time Toxins Vaccines Vaccines, Synthetic - chemistry Vaccines, Synthetic - immunology Spray dry Plant-produced Protective antigen Stability Anthrax
Online Access	Get full text
ISSN	0264-410X 1873-2518 1873-2518
DOI	10.1016/j.vaccine.2016.12.009

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Abstract	Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the rPA vaccines are highly purified preparations of only rPA. These second generation rPA vaccines strive to elicit strong immune responses with substantially fewer doses than AVA while provoking less side effects. Many of the rPA candidates have shown to be effective in pre-clinical studies, but most of the second generation molecules have stability issues which reduce their efficacy over time. These stability issues are evident even under refrigerated conditions and thus emphasis has been directed to stabilizing the rPA molecule and determining an optimized final formulation. Stabilization of vaccines for long-term storage is a major challenge in the product development life cycle. The effort required to identify suitable formulations can be slow and expensive. The ideal storage for stockpiled vaccines would allow the candidate to withstand years of storage at ambient temperatures. The Fraunhofer Center for Molecular Biotechnology is developing a plant-produced rPA vaccine candidate that shows instability when stored under refrigerated conditions in a solution, as is typical for rPA vaccines. Increased stability of our plant-produced rPA vaccine candidate was achieved in a spray dried powder formulation that could eliminate the need for conventional cold chain allowing greater confidence to stockpile vaccine for civilian and military biodefense.
AbstractList	Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the rPA vaccines are highly purified preparations of only rPA. These second generation rPA vaccines strive to elicit strong immune responses with substantially fewer doses than AVA while provoking less side effects. Many of the rPA candidates have shown to be effective in pre-clinical studies, but most of the second generation molecules have stability issues which reduce their efficacy over time. These stability issues are evident even under refrigerated conditions and thus emphasis has been directed to stabilizing the rPA molecule and determining an optimized final formulation. Stabilization of vaccines for long-term storage is a major challenge in the product development life cycle. The effort required to identify suitable formulations can be slow and expensive. The ideal storage for stockpiled vaccines would allow the candidate to withstand years of storage at ambient temperatures. The Fraunhofer Center for Molecular Biotechnology is developing a plant-produced rPA vaccine candidate that shows instability when stored under refrigerated conditions in a solution, as is typical for rPA vaccines. Increased stability of our plant-produced rPA vaccine candidate was achieved in a spray dried powder formulation that could eliminate the need for conventional cold chain allowing greater confidence to stockpile vaccine for civilian and military biodefense. Abstract Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the rPA vaccines are highly purified preparations of only rPA. These second generation rPA vaccines strive to elicit strong immune responses with substantially fewer doses than AVA while provoking less side effects. Many of the rPA candidates have shown to be effective in pre-clinical studies, but most of the second generation molecules have stability issues which reduce their efficacy over time. These stability issues are evident even under refrigerated conditions and thus emphasis has been directed to stabilizing the rPA molecule and determining an optimized final formulation. Stabilization of vaccines for long-term storage is a major challenge in the product development life cycle. The effort required to identify suitable formulations can be slow and expensive. The ideal storage for stockpiled vaccines would allow the candidate to withstand years of storage at ambient temperatures. The Fraunhofer Center for Molecular Biotechnology is developing a plant-produced rPA vaccine candidate that shows instability when stored under refrigerated conditions in a solution, as is typical for rPA vaccines. Increased stability of our plant-produced rPA vaccine candidate was achieved in a spray dried powder formulation that could eliminate the need for conventional cold chain allowing greater confidence to stockpile vaccine for civilian and military biodefense. Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the rPA vaccines are highly purified preparations of only rPA. These second generation rPA vaccines strive to elicit strong immune responses with substantially fewer doses than AVA while provoking less side effects. Many of the rPA candidates have shown to be effective in pre-clinical studies, but most of the second generation molecules have stability issues which reduce their efficacy over time. These stability issues are evident even under refrigerated conditions and thus emphasis has been directed to stabilizing the rPA molecule and determining an optimized final formulation. Stabilization of vaccines for long-term storage is a major challenge in the product development life cycle. The effort required to identify suitable formulations can be slow and expensive. The ideal storage for stockpiled vaccines would allow the candidate to withstand years of storage at ambient temperatures. The Fraunhofer Center for Molecular Biotechnology is developing a plant-produced rPA vaccine candidate that shows instability when stored under refrigerated conditions in a solution, as is typical for rPA vaccines. Increased stability of our plant-produced rPA vaccine candidate was achieved in a spray dried powder formulation that could eliminate the need for conventional cold chain allowing greater confidence to stockpile vaccine for civilian and military biodefense.Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in immunized subjects. The main difference between the rPA vaccines compared to the current licensed vaccine, anthrax vaccine absorbed (AVA), is the rPA vaccines are highly purified preparations of only rPA. These second generation rPA vaccines strive to elicit strong immune responses with substantially fewer doses than AVA while provoking less side effects. Many of the rPA candidates have shown to be effective in pre-clinical studies, but most of the second generation molecules have stability issues which reduce their efficacy over time. These stability issues are evident even under refrigerated conditions and thus emphasis has been directed to stabilizing the rPA molecule and determining an optimized final formulation. Stabilization of vaccines for long-term storage is a major challenge in the product development life cycle. The effort required to identify suitable formulations can be slow and expensive. The ideal storage for stockpiled vaccines would allow the candidate to withstand years of storage at ambient temperatures. The Fraunhofer Center for Molecular Biotechnology is developing a plant-produced rPA vaccine candidate that shows instability when stored under refrigerated conditions in a solution, as is typical for rPA vaccines. Increased stability of our plant-produced rPA vaccine candidate was achieved in a spray dried powder formulation that could eliminate the need for conventional cold chain allowing greater confidence to stockpile vaccine for civilian and military biodefense.
Author	Jones, R. Mark Dubose, Devon Manceva, Slobodanka Chichester, Jessica A. Breit, Jeff Streatfield, Stephen J. Burke, Michael Horsey, April Yusibov, Vidadi
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Keywords	Spray dry Plant-produced Protective antigen Stability Anthrax
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Snippet	Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses in... Abstract Second generation anthrax vaccines focus on the use of recombinant protective antigen (rPA) to elicit a strong, toxin neutralizing antibody responses...
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SubjectTerms	adverse effects Allergy and Immunology Ambient temperature Animals Anthrax Anthrax - immunology Anthrax Vaccines - blood Anthrax Vaccines - immunology Antibodies, Bacterial Antibodies, Neutralizing - immunology Antigens Antigens, Bacterial - immunology Bacillus anthracis - immunology Bacterial Toxins - immunology Biotechnology Chemistry, Pharmaceutical - methods Chromatography cold Drug Stability Drug Storage - methods Edema Formulations Immune response Immunization Immunization - methods Life cycle engineering Life cycle product development Life cycles Mice Mice, Inbred BALB C neutralization neutralizing antibodies Peptides Plant-produced Plants - chemistry Powder Powders - chemistry Product development Protective antigen Proteins Scanning electron microscopy Side effects Spray dry spray drying Stability storage storage time Toxins Vaccines Vaccines, Synthetic - chemistry Vaccines, Synthetic - immunology
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Title	Stability and pre-formulation development of a plant-produced anthrax vaccine candidate
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