CI

At a glance

ClinicalIndex Comparison Record
Phase 1Completed· 11 enrolled
Drug / intervention
BCGbiological
Likely dose
BCG 0.1mlfrom record
Structured eligibility isn't available for this trial yet — see the full criteria in the Eligibility tab below.

Standardized by ClinicalIndex from the ClinicalTrials.gov record · verify against the source.

Search/NCT00654316
NCT00654316Phase 1Completed

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.

University of Oxford·interventional·Posted Apr 7, 2008·Updated Apr 7, 2008

In Brief

A Phase 1 clinical trial evaluating BCG for TB. Completed, enrolled 11 participants across 1 site.

Detailed Summary

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.

Study Details

Study Typeinterventional
Allocation--
Masking--
Primary Purpose--
ConditionsTB
CountriesUnited Kingdom
Collaborators--

Timeline

Phase 1CompletedFinished
200420052006200720082009201020112012201320142015201620172018201920202021202220232024202520262027
First PostedApr 7, 2008
Enrollment StartFeb 1, 2004
Primary CompletionNov 1, 2005
TodayJul 2, 2026
Enrollment to primary: 1.8 yearsPosted 18.2 years ago

Interventions

BCGbiological

intradermal injection of 0.1ml BCG over the deltoid muscle