Infectious Disease

Aida Badiane of the Universite Cheikh Anta Diop de Dakar in Senegal will use shotgun metagenomic next generation sequencing (mNGS) to identify the pathogens causing nosocomial infections in Senegal to improve diagnosis and treatment. Nosocomial infections (i.e., hospital-acquired) cause substantial mortality in Senegal but remain poorly understood. To create a more complete profile of the causative pathogens, they will apply shotgun mNGS to different types of clinical samples from 61 patients at LeDantec hospital to identify and quantify the pathogens.

Munyaradzi Musvosvi of the University of Cape Town in South Africa will determine whether a valuable biomarker of tuberculosis (TB) can be measured in small volumes of blood collected by finger-prick together with an automated, low-cost processing approach to accelerate diagnoses in low-resource settings. Individuals with TB have higher levels of a specific activation marker on the surface of some of their T cells, which could be a valuable diagnostic target.

Penny Moore of the National Institute for Communicable Diseases in South Africa together with Adriana Bonomo of Fiocruz in Brazil will identify solutions for combating new SARS-CoV-2 variants by developing an in vitro assay to predict new variants and identifying broad specificity antibodies for use as new drugs and diagnostics. Despite the success of vaccines and antibody therapies, the continual emergence of new viral variants, which thwart our immune defenses and therapies, remains a major challenge of the pandemic.

Seth Bloom of Massachusetts General Hospital in the U.S. together with Sinaye Ngcapu of the Center for the AIDS Programme of Research (CAPRISA) in South Africa will investigate how bacterial vaginosis (BV) and non-Lactobacillus-dominated vaginal microbiota elevate the risk of contracting HIV-1 to help develop preventative therapies. South Africa has high rates of BV and microbiota-associated vaginal HIV transmission but the underlying mechanisms are unknown, which makes it difficult to prevent.

Jurriaan de Steenwinkel of the Erasmus Medical Center Rotterdam in the Netherlands together with Eric Nuermberger of Johns Hopkins University in the U.S. will combine expertise to develop a robust, preclinical mouse model of latent tuberculosis (TB) together with a molecular assay for measuring candidate drug activity to boost drug development. Reducing latent TB infections is essential to meet the goal of the World Health Organization’s End TB Strategy but current drugs have limited effect and measuring the activity of candidate compounds in latent infections is challenging.

Peter van Heusden of the University of the Western Cape in South Africa together with Placide Mbala of the Institut National de Récherche Biomedicale in the DRC will establish in-house pathogen sequencing capabilities at a research institute in the DRC to enable rapid responses to meningitis outbreaks and improve patient outcomes. Despite the success of vaccines, meningitis outbreaks caused by diverse bacterial species still cause substantial fatalities across Africa.

Lye McKinnon of the University of Manitoba in Canada together with Ali Ssetaala of the Uganda Virus Research Institute in Uganda will determine whether nasal mucosal immune responses induced by COVID-19 vaccines and natural infection can help prevent infection and transmission. Although COVID-19 mRNA vaccines effectively prevent severe disease, they are less effective at preventing transmission, which is critical for protecting vulnerable populations particularly against emerging, highly transmissible variants.

Adriana Bonomo of Fiocruz in Brazil together with Penny Moore of the National Institute for Communicable Diseases in South Africa will identify solutions for combating new SARS-CoV-2 variants by developing an in vitro assay to predict new variants and identifying broad specificity antibodies for use as new drugs and diagnostics. Despite the success of vaccines and antibody therapies, the continual emergence of new viral variants, which thwart our immune defenses and therapies, remains a major challenge of the pandemic.

Nitin Baliga of the Institute for Systems Biology in the U.S. together with Google Applied Science will combine systems biology with machine learning and artificial intelligence to accelerate the discovery of more effective and affordable treatments for tuberculosis. Tuberculosis kills 1.5 million people annually, but developing novel treatments is expensive using current methods and complicated by the different physiological states and sub-populations of the causative Mycobacterium tuberculosis.

Chijioke Kaduru of Corona Management Systems in Nigeria will strengthen malaria mathematical modeling capability and capacity in Nigeria by building a fellowship program for field epidemiologists and current doctorate students in epidemiology. The program will be embedded within the Nigeria Field Epidemiology Training Program (NFETP), which is managed and coordinated by the Nigeria Centre for Disease Control.