Tuberculosis is a persistent human pathogen that threatens the health of people throughout the world, especially in developing countries. Although tuberculosis is both a treatable and preventable condition, current public health strategies that focus on directly observed therapy have failed to control the disease in Sub-Saharan Africa where tuberculosis control is compounded by the HIV epidemic, the emergence of multi-drug resistant disease, and fragile infrastructure for public health. One reason for the limited success of this strategy is that it is a prescription of treatment of tuberculosis, it doesnot prevent subsequent cases among contacts of infectious cases. This proposal is designed around a new paradigm for tuberculosis control that is built upon a basic tenet in epidemic theory. That is, tuberculosis epidemics are perpetuated when one case is replaced by one or more cases among contacts. Unless subsequent cases are prevented, there will be little progress with tuberculosis control. Case studies, molecular epidemiology and community trials all point to transmission in the community as the driving force behind tuberculosis epidemics. The scientific goal of this project is to understand transmission of M. tuberculosis in an urban African setting. The extended, applied goal is to add cost-effective strategies aimed at interrupting transmission of M. tuberculosis to current global approaches to tuberculosis control. To address the Specific Aims of this proposal, we will conduct two inter-related epidemiologic studies in the Rubaga Division of Kampala Uganda. We will perform a cross-sectional study that compares the social networks, mixing patterns, microbial networks, individual risk characteristics, and geographic context between index tuberculosis cases and neighborhood matched controls. We will also perform a case- cohort study within a prospective cohort to determine the incidence of new tuberculosis infection and relate it to high risk environments, mixing patterns and geographic location of social networks. This application has been revised according to the recommendations of the study section and now includes the results of a pilot project. The results further support the basic premise of the study and show its feasibility. The proposed projects will integrate methods from diverse fields such as molecular epidemiology, social network analysis, and geographic information systems to open up a new way to approach tuberculosis control that will exert a sustained and powerful influence on the field.
This proposal addresses the globally important problem of tuberculosis. Through the study of social networks of tuberculosis cases, the project will seek to fill gaps in our knowledge about the spread of tuberculosis in African cities. By the conclusion of this project, we hope to have valid evidence on which to base new ways to control tuberculosis that mitigate or block transmission.
|Martinez, Leonardo; Handel, Andreas; Shen, Ye et al. (2018) A Prospective Validation of a Clinical Algorithm to Detect Tuberculosis in Child Contacts. Am J Respir Crit Care Med 197:1214-1216|
|Martinez, Leonardo; Shen, Ye; Handel, Andreas et al. (2018) Effectiveness of WHO's pragmatic screening algorithm for child contacts of tuberculosis cases in resource-constrained settings: a prospective cohort study in Uganda. Lancet Respir Med 6:276-286|
|Sekandi, Juliet N; Zalwango, Sarah; Nkwata, Allan K et al. (2018) Low Prevalence of Tuberculin Skin Test Boosting among Community Residents in Uganda. Am J Trop Med Hyg 98:379-381|
|Martinez, Leonardo; Shen, Ye; Mupere, Ezekiel et al. (2017) Transmission of Mycobacterium Tuberculosis in Households and the Community: A Systematic Review and Meta-Analysis. Am J Epidemiol 185:1327-1339|
|Martinez, Leonardo; Xu, Lin; Chen, Cheng et al. (2017) Delays and Pathways to Final Tuberculosis Diagnosis in Patients from a Referral Hospital in Urban China. Am J Trop Med Hyg 96:1060-1065|
|Mutembo, Simon; Mutanga, Jane N; Musokotwane, Kebby et al. (2016) Antiretroviral therapy improves survival among TB-HIV co-infected patients who have CD4+ T-cell count above 350cells/mm(3). BMC Infect Dis 16:572|
|Menzies, Nicolas A; Gomez, Gabriela B; Bozzani, Fiammetta et al. (2016) Cost-effectiveness and resource implications of aggressive action on tuberculosis in China, India, and South Africa: a combined analysis of nine models. Lancet Glob Health 4:e816-e826|
|Whalen, Christopher C (2016) The Replacement Principle of Tuberculosis. Why Prevention Matters. Am J Respir Crit Care Med 194:400-1|
|Martinez, Leonardo; Sekandi, Juliet N; Castellanos, María E et al. (2016) Infectiousness of HIV-Seropositive Patients with Tuberculosis in a High-Burden African Setting. Am J Respir Crit Care Med 194:1152-1163|
|Ma, Mai-Juan; Yang, Yang; Wang, Hai-Bin et al. (2015) Transmissibility of tuberculosis among school contacts: an outbreak investigation in a boarding middle school, China. Infect Genet Evol 32:148-55|
Showing the most recent 10 out of 17 publications