Your search keyword '"Kasongo Webster"' showing total 3 results

1. Zambia Assessment of Tuberculosis (TB) and HIV in the Mines (ZATHIM): implications for programs and policies

Author

Podewils, Laura Jean, Long, Elizabeth F., Fuller, Tyler J., Mwakazanga, David, Kapungu, Kelvin, Tembo, Mathias, Mwanza, Sydney, Curran, Kathryn G., Smith, Jonathan P., Tobias, James L., and Kasongo, Webster

Published

2022

2. Geospatial distribution of Mycobacterium tuberculosis genotypes in Africa.

Author

Chihota, Violet N., Niehaus, Antoinette, Streicher, Elizabeth M., Wang, Xia, Sampson, Samantha L., Mason, Peter, Källenius, Gunilla, Mfinanga, Sayoki G., Pillay, Marnomorney, Klopper, Marisa, Kasongo, Webster, Behr, Marcel A., Gey van Pittius, Nicolaas C., van Helden, Paul D., Couvin, David, Rastogi, Nalin, and Warren, Robin M.

Subjects

MYCOBACTERIUM tuberculosis, GEOGRAPHICAL distribution of bacteria, GENOTYPES, LINEAGE, HIERARCHICAL clustering (Cluster analysis)

Abstract

Objective: To investigate the distribution of Mycobacterium tuberculosis genotypes across Africa. Methods: The SITVIT2 global repository and PUBMED were searched for spoligotype and published genotype data respectively, of M. tuberculosis from Africa. M. tuberculosis lineages in Africa were described and compared across regions and with those from 7 European and 6 South-Asian countries. Further analysis of the major lineages and sub-lineages using Principal Component analysis (PCA) and hierarchical cluster analysis were done to describe clustering by geographical regions. Evolutionary relationships were assessed using phylogenetic tree analysis. Results: A total of 14727 isolates from 35 African countries were included in the analysis and of these 13607 were assigned to one of 10 major lineages, whilst 1120 were unknown. There were differences in geographical distribution of major lineages and their sub-lineages with regional clustering. Southern African countries were grouped based on high prevalence of LAM11-ZWE strains; strains which have an origin in Portugal. The grouping of North African countries was due to the high percentage of LAM9 strains, which have an origin in the Eastern Mediterranean region. East African countries were grouped based on Central Asian (CAS) and East-African Indian (EAI) strain lineage possibly reflecting historic sea trade with Asia, while West African Countries were grouped based on Cameroon lineage of unknown origin. A high percentage of the Haarlem lineage isolates were observed in the Central African Republic, Guinea, Gambia and Tunisia, however, a mixed distribution prevented close clustering. Conclusions: This study highlighted that the TB epidemic in Africa is driven by regional epidemics characterized by genetically distinct lineages of M. tuberculosis. M. tuberculosis in these regions may have been introduced from either Europe or Asia and has spread through pastoralism, mining and war. The vast array of genotypes and their associated phenotypes should be considered when designing future vaccines, diagnostics and anti-TB drugs. [ABSTRACT FROM AUTHOR]

Published

2018

3. Artemisinin-based combination therapy in pregnant women in Zambia: efficacy, safety and risk of recurrent malaria.

Author

Nambozi, Michael, Bukasa Kabuya, Jean-Bertin, Hachizovu, Sebastian, Mwakazanga, David, Mulenga, Joyce, Kasongo, Webster, Buyze, Jozefien, Mulenga, Modest, Van Geertruyden, Jean-Pierre, and D'Alessandro, Umberto

Subjects

ARTEMISININ, COMBINATION drug therapy, MALARIA prevention, DRUG efficacy, MEDICATION safety, THERAPEUTICS

Abstract

Background: In Zambia, malaria is one of the leading causes of morbidity and mortality, especially among under five children and pregnant women. For the latter, the World Health Organization recommends the use of artemisinin-based combination therapy (ACT) in the second and third trimester of pregnancy. In a context of limited information on ACT, the safety and efficacy of three combinations, namely artemether-lumefantrine (AL), mefloquine-artesunate (MQAS) and dihydroartemisinin-piperaquine (DHAPQ) were assessed in pregnant women with malaria. Methods: The trial was carried out between July 2010 and August 2013 in Nchelenge district, Luapula Province, an area of high transmission, as part of a multi-centre trial. Women in the second or third trimester of pregnancy and with malaria were recruited and randomized to one of the three study arms. Women were actively followed up for 63 days, and then at delivery and 1 year post-delivery. Results: Nine hundred pregnant women were included, 300 per arm. PCR-adjusted treatment failure was 4.7% (12/258) (95% CI 2.7-8.0) for AL, 1.3% (3/235) (95% CI 0.4-3.7) for MQAS and 0.8% (2/236) (95% CI 0.2-3.0) for DHAPQ, with significant risk difference between AL and DHAPQ (p = 0.01) and between AL and MQAS (p = 0.03) treatments. Re-infections during follow up were more frequent in the AL (HR: 4.71; 95% CI 3.10-7.2; p < 0.01) and MQAS (HR: 1.59; 95% CI 1.02-2.46; p = 0.04) arms compared to the DHAPQ arm. PCR-adjusted treatment failure was significantly associated with women under 20 years [Hazard Ratio (HR) 5.35 (95% CI 1.07-26.73; p = 0.04)] and higher malaria parasite density [3.23 (95% CI 1.03-10.10; p = 0.04)], and still women under 20 years [1.78, (95% CI 1.26-2.52; p < 0.01)] had a significantly higher risk of re-infection. The three treatments were generally well tolerated. Dizziness, nausea, vomiting, headache and asthenia as adverse events (AEs) were more common in MQAS than in AL or DHAPQ (p < 0.001). Birth outcomes were not significantly different between treatment arms. Conclusion: As new infections can be prevented by a long acting partner drug to the artemisinins, DHAPQ should be preferred in places as Nchelenge district where transmission is intense while in areas of low transmission intensity AL or MQAS may be used. [ABSTRACT FROM AUTHOR]

Published

2017