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University of Oxford |
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Information provided by: | University of Oxford |
ClinicalTrials.gov Identifier: | NCT00654316 |
Tuberculosis (TB) kills about three million people annually. It is estimated that one third of the world's population are latently infected with Mycobacterium tuberculosis (M.tb). Multi-drug resistant strains of M.tb, and co-infection with M.tb and HIV present major new challenges. The currently available vaccine, M. bovis BCG, is largely ineffective at protecting against adult pulmonary disease in endemic areas and it is widely agreed that a new more effective tuberculosis vaccine is a major global public health priority1. However, it may be unethical and impractical to test and deploy a vaccine strategy that does not include BCG, as BCG does confer worthwhile protection against TB meningitis and leprosy. An immunisation strategy that includes BCG is also attractive because the populations in which this vaccine candidate will need to be tested will already have been immunised with BCG.
M.tb is an intracellular organism. CD4+ Th1-type cellular responses are essential for protection and there is increasing evidence from animal and human studies that CD8+ T cells also play a protective role2. However, it has generally been difficult to induce strong cellular immune responses in humans using subunit vaccines. DNA vaccines induce both CD4+ and CD8+ T cells and thus offer a potential new approach to a TB vaccine. DNA vaccines encoding various antigens from M. tuberculosis have been evaluated in the murine model, and to date no DNA vaccine alone has been shown to be superior to BCG.
A heterologous prime-boost immunisation strategy involves giving two different vaccines, each encoding the same antigen, several weeks apart. Such regimes are extremely effective at inducing a cellular immune response. Using a DNA- prime/MVA-boost immunisation strategy induces high levels of CD8+ T cells in animal models of malaria and HIV5, and high levels of both CD4+ and CD8+ T cells in animal models of TB. BCG immunisation alone induces only CD4+ T cells in mice. A prime-boost strategy using BCG as the prime and a recombinant MVA encoding an antigen from M.tb that is also present in BCG (antigen 85A: 'MVA85A') as the boost, induces much higher levels of CD4+ T cells than BCG or MVA85A alone. In addition, this regime generates specific CD8+ T cells that are undetectable following immunisation with BCG alone.
Condition | Intervention | Phase |
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TB |
Biological: BCG |
Phase I |
Study Type: | Interventional |
Study Design: | Prevention, Non-Randomized, Open Label, Uncontrolled, Single Group Assignment, Safety/Efficacy Study |
Official Title: | A Phase I Study of the Safety and Immunogenicity of BCG (Bacille Calmette-Guerin) Vaccine Delivered Intradermally by a Needle Injection in Healthy Volunteers Who Have Previously Received BCG. |
Enrollment: | 11 |
Study Start Date: | February 2004 |
Study Completion Date: | November 2005 |
Primary Completion Date: | November 2005 (Final data collection date for primary outcome measure) |
Arms | Assigned Interventions |
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1: Experimental
BCG delivered intradermally into the deltoid region in volunteers who have received BCG 10 - 20 years previously.
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Biological: BCG
intradermal injection of 0.1ml BCG over the deltoid muscle
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Recombinant viruses as vaccines.
Recombinant viruses used alone have for some years represented a promising vaccine delivery system, particularly for inducing cellular immune responses8. The recombinant virus encodes the immunising protein or peptide. Immunisation by a recombinant virus vaccine occurs when host cells take up and express the inoculated attenuated virus encoding a protective antigen. The expressed protein often has the native conformation, glycosylation, and other post-translational modifications that occur during natural infection. Recombinant viral vaccines may elicit both antibody and cytotoxic T-lymphocyte responses, which persist without further immunisations.
Many viruses have been investigated as potential recombinant vaccines. The successful worldwide eradication of smallpox via vaccination with live vaccinia virus highlighted vaccinia as a candidate for recombinant use. The recognition in recent years that non-replicating strains of poxvirus such as MVA and avipox vectors can be more immunogenic than traditional replicating vaccinia strains has enhanced the attractiveness of this approach. MVA (modified vaccinia virus Ankara) is a strain of vaccinia virus which has been passaged more than 570 times though avian cells, is replication incompetent in human cell lines and has a good safety record. It has been administered to more than 120,000 vaccinees as part of the smallpox eradication programme, with no adverse effects, despite the deliberate vaccination of high risk groups. This safety in man is consistent with the avirulence of MVA in animal models. MVA has six major genomic deletions compared to the parental genome severely compromising its ability to replicate in mammalian cells. Viral replication is blocked late during infection of cells but importantly viral and recombinant protein synthesis is unimpaired even during this abortive infection. Replication-deficient recombinant MVA has been seen as an exceptionally safe viral vector. When tested in animal model studies recombinant MVAs have been shown to be avirulent, yet protectively immunogenic as vaccines against viral diseases and cancer. The most useful data on the safety and efficacy of various doses of a recombinant MVA vaccine comes from clinical trial data with a recombinant MVA expressing a number of CTL epitopes from Plasmodium falciparum pre-erythrocytic antigens fused to a complete pre-erythrocytic stage antigen, Thrombospondin Related Adhesion Protein (TRAP). These trials have given a total of 169 immunisations with this recombinant MVA, to 49 UK vaccinees 38 Gambian vaccines (20 of whom were children aged 1-5). 6 doses of 1 x 10^7 pfu, 139 doses of 5 x 10^7 pfu, 6 doses of 1 x 10^8 pfu and 18 doses of 2.5 x 10^8 pfu have been administered, all without serious adverse effects.
Recombinant MVA encoding antigen 85A
Secreted antigens from M. tuberculosis are released from actively metabolising bacteria, and are important targets in protective immunity. Antigen 85A is a major secreted antigen from M. tuberculosis which forms part of the antigen 85 complex (A, B and C). This complex constitutes a major portion of the secreted proteins of both M.tb and BCG. It is involved in fibronectin binding within the cell wall and has mycolyltransferase activity.
MVA85A induces both a CD4+ and a CD8+ epitope when used to immunise mice. When mice are primed with BCG and then given MVA85A as a boost, the levels of CD4+ and CD8+ T cells induced are higher than with either BCG or MVA85A alone.
We are evaluating the safety and immunogenicity of the following 3 groups:
BCG-BCG provides a control group for BCG-MVA85A. Many countries have a tradition of repeated BCG vaccination and the criteria for revaccination differ between countries.
Ages Eligible for Study: | 18 Years to 55 Years |
Genders Eligible for Study: | Both |
Accepts Healthy Volunteers: | Yes |
Inclusion Criteria:
Exclusion Criteria:
United Kingdom, Oxfordshire | |
Centre for Clinical Vaccinology and Tropical Medicine | |
Oxford, Oxfordshire, United Kingdom, OX3 7LJ |
Principal Investigator: | Helen McShane | University of Oxford |
Responsible Party: | University of Oxford ( Dr Helen McShane ) |
Study ID Numbers: | TB006 |
Study First Received: | April 2, 2008 |
Last Updated: | April 4, 2008 |
ClinicalTrials.gov Identifier: | NCT00654316 |
Health Authority: | United Kingdom: Medicines and Healthcare Products Regulatory Agency |
TB Tuberculosis MVA85A Vaccine BCG |
Tuberculosis Healthy |