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Clinical Trial Summary

Despite tremendous efforts, an effective tuberculosis (TB) vaccine remains elusive. TB continues to infect and kill many. In 2021, TB infected more than 10 million and killed 1.6 million people. To date, the M.bovis bacille Calmette Guerin (BCG) is the only licensed vaccine against tuberculosis (TB). Efforts to come up with new and effective vaccines have not been successful. Partially, the lack of suitable disease models and protection correlates hinders the research of new vaccines. Controlled human infection model studies (CHIM) involve administering disease-causing microbes to healthy individuals, with continued monitoring of disease response. These studies have been used to study malaria, typhoid, pneumococcal pneumonia and the recent SARS-CoV-2 vaccines. The BCG-Controlled Human Infection Model (BCG-CHIM) will allow accurate dosing with safe mycobacteria as well as minimal tissue sampling to understand immunity to mycobacteria. Considering that the M. bovis BCG is a safe living Mycobacteria, it can be used as a CHIM against which to test new vaccines.


Clinical Trial Description

Tuberculosis (TB) is a leading cause of death from a single infectious agent worldwide and is an acknowledged major challenge in Malawi. Globally in 2021, there were an estimated 10.6 million people unwell with TB and an estimated 1.6 million deaths caused by TB. Furthermore, the global TB incidence could be accelerated to an average of 17% per year between 2025 and 2035 owing to the disruption to TB services caused by the COVID pandemic. TB diagnosis is challenging, and drug treatment can be prolonged, harmful, costly, and complex, especially in the increasingly common context of drug resistant M. tuberculosis. For these reasons an effective vaccine to prevent disease is a global public health priority, and drugs to allow shorter courses of effective therapy are urgently needed. At present, the only licensed vaccine is the bacille Calmette-Guérin (BCG) vaccine (BCG Bulgaria is the Malawi licensed strain). BCG has been administered globally to several billion people over the last 100 years and it has been part of the expanded program on immunisations since the early-1970s. BCG is effective in preventing disseminated TB disease, including tuberculous meningitis in childhood. However, it does not protect against pulmonary TB in many parts of the world, especially in the tropics where the incidence of TB is at its greatest. Since pulmonary TB is associated with the highest morbidity and mortality, the need to develop an effective vaccine against this disease is paramount, especially in Malawi where BCG protection is known to be minimal. There are several novel vaccines for TB in clinical development, the most clinically advanced of which is M72/AS01E. The evaluation of candidate TB vaccines is challenging, and progress in the field is hampered by the lack of an immunological correlate of protection. Most routinely administered vaccines generate a quantifiable antibody response that correlates strongly with protection. In contrast, protection against TB is critically dependent on the cellular immune response, in particular CD4+ and also probably CD8+ T cell mediated cellular responses. The mechanisms of these responses are not fully understood . Currently, to assess vaccine efficacy against TB there is no alternative to large randomized controlled trials. These efficacy trials for novel TB vaccines are difficult, long and very costly. For this reason, there is an urgent need for a valid, reliable, and strong evaluation technique to help distinguish between candidate TB vaccines' likely efficacy at Phase 3. Candidate vaccines which have passed successfully through phase I trials and are in Phase 2b efficacy studies could be included in human challenge protocols which could be designed to either measure prevention of infection (POI) or immunological endpoints. This would allow vaccine discovery to accelerate in a cost-effective manner. Similarly, successful development of new, safe and effective TB therapies face multiple challenges. A responsive controlled human infection model of TB infection could accelerate the development of new drugs and promote refinement of drug combination regimens. Controlled human infection models (CHIMs) provide insight into disease pathogenesis and correlates of immune protection to support the development of novel vaccines. The Malawi Liverpool Wellcome Trust has extensive experience of delivering CHIM studies in Malawi with Streptococcus pneumoniae and established technology transfer processes with previous successful transfer of the experimental human pneumococcal carriage model from Liverpool to Blantyre, Malawi. Before the Malawi BCG study, the team will also confirm feasibility of this established BCG model in Liverpool. The Liverpool team will be able to share techniques and expertise and compare data as the Liverpool population will have a different experience of BCG and tuberculosis in the community and are likely to show different results. A TB CHIM established in both the UK and Malawi has the potential to rapidly advance development of vaccines and therapeutics fit for use in populations that need them most. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT06178666
Study type Interventional
Source Liverpool School of Tropical Medicine
Contact Stephen B Gordon, MD
Phone 265992552382
Email sgordon@mlw.mw
Status Not yet recruiting
Phase N/A
Start date March 1, 2024
Completion date March 1, 2026

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