Browsing by Author "Mulei, Sophia"
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Item Epidemiology and Surveillance of Influenza Viruses in Uganda between 2008 and 2014(PLoS ONE, 2016) Wabwire-Mangen, Fred; Mimbe, Derrick E.; Erima, Bernard; Mworozi, Edison A.; Millard, Monica; Kibuuka, Hannah; Lukwago, Luswa; Bwogi, Josephine; Kiconco, Jocelyn; Tugume, Titus; Mulei, Sophia; Ikomera, Christine; Tsui, Sharon; Malinzi, Stephen; Kasasa, Simon; Coldren, Rodney; Byarugaba, Denis K.Influenza surveillance was conducted in Uganda from October 2008 to December 2014 to identify and understand the epidemiology of circulating influenza strains in out-patient clinic attendees with influenza-like illness and inform control strategies. Methodology Surveillance was conducted at five hospital-based sentinel sites. Nasopharyngeal and/or oropharyngeal samples, epidemiological and clinical data were collected from enrolled patients. Real-time reverse transcription polymerase chain reaction (RT-PCR) was performed to identify and subtype influenza strains. Data were double-entered into an Epi Info 3.5.3 database and exported to STATA 13.0 software for analysis. Results Of the 6,628 patient samples tested, influenza virus infection was detected in 10.4% (n = 687/ 6,628) of the specimens. Several trends were observed: influenza circulates throughout the year with two peaks; the major one from September to November and a minor one from March to June. The predominant strains of influenza varied over the years: Seasonal Influenza A(H3) virus was predominant from 2008 to 2009 and from 2012 to 2014; Influenza A (H1N1)pdm01 was dominant in 2010; and Influenza B virus was dominant in 2011. The peaks generally coincided with times of higher humidity, lower temperature, and higher rainfall. Conclusion Influenza circulated throughout the year in Uganda with two major peaks of outbreaks with similar strains circulating elsewhere in the region. Data on the circulating strains of influenza and its patterns of occurrence provided critical insights to informing the design and timing of influenza vaccines for influenza prevention in tropical regions of sub-Saharan Africa.Item First Laboratory-Confirmed Outbreak of Human and Animal Rift Valley Fever Virus in Uganda in 48 Years(The American journal of tropical medicine and hygiene, 2019) Shoemaker, Trevor R.; Nyakarahuka, Luke; Balinandi, Stephen; Ojwang, Joseph; Tumusiime, Alex; Mulei, Sophia; Kyondo, Jackson; Lubwama, Bernard; Sekamatte, Musa; Namutebi, Annemarion; Tusiime, Patrick; Monje, Fred; Mayanja, Martin; Ssendagire, Steven; Dahlke, Melissa; Kyazze, Simon; Wetaka, Milton; Makumbi, Issa; Borchert, Jeff; Zufan, Sara; Patel, Ketan; Whitmer, Shannon; Brown, Shelley; Davis, William G.; Klena, John D.; Nichol, Stuart T.; Rollin, Pierre E.; Lutwama, JuliusIn March 2016, an outbreak of Rift Valley fever (RVF) was identified in Kabale district, southwestern Uganda. A comprehensive outbreak investigation was initiated, including human, livestock, and mosquito vector investigations. Overall, four cases of acute, nonfatal human disease were identified, three by RVF virus (RVFV) reverse transcriptase polymerase chain reaction (RT-PCR), and one by IgM and IgG serology. Investigations of cattle, sheep, and goat samples from homes and villages of confirmed and probable RVF cases and the Kabale central abattoir found that eight of 83 (10%) animals were positive for RVFV by IgG serology; one goat from the home of a confirmed case tested positive by RT-PCR. Whole genome sequencing from three clinical specimens was performed and phylogenetic analysis inferred the relatedness of 2016 RVFV with the 2006–2007 Kenya-2 clade, suggesting previous introduction of RVFV into southwestern Uganda. An entomological survey identified three of 298 pools (1%) of Aedes and Coquillettidia species that were RVFV positive by RT-PCR. This was the first identification of RVFV in Uganda in 48 years and the 10th independent viral hemorrhagic fever outbreak to be confirmed in Uganda since 2010.Item Prevalence of influenza A viruses in livestock and free-living waterfowl in Uganda(BMC Veterinary Research, 2014) Kirunda, Halid; Erima, Bernard; Tumushabe, Agnes; Kiconco, Jocelyn; Tugume, Titus; Mulei, Sophia; Mimbe, Derrick; Mworozi, Edison; Bwogi, Josephine; Luswa, Lukwago; Kibuuka, Hannah; Millard, Monica; Byaruhanga, Achilles; Ducatez, Mariette F.; Krauss, Scott; Webby, Richard J.; Webster, Robert G.; Wurapa, Kofi; Byarugaba, Denis K.; Wabwire-Mangen, FredAvian influenza viruses may cause severe disease in a variety of domestic animal species worldwide, with high mortality in chickens and turkeys. To reduce the information gap about prevalence of these viruses in animals in Uganda, this study was undertaken. Results: Influenza A virus prevalence by RT-PCR was 1.1% (45/4,052) while sero prevalence by ELISA was 0.8% (24/2,970). Virus prevalence was highest in domestic ducks (2.7%, 17/629) and turkeys (2.6%, 2/76), followed by free-living waterfowl (1.3%, 12/929) and swine (1.4%, 7/511). A lower proportion of chicken samples (0.4%, 7/1,865) tested positive. No influenza A virus was isolated. A seasonal prevalence of these viruses in waterfowl was 0.7% (4/561) for the dry and 2.2% (8/368) for the wet season. In poultry, prevalence was 0.2% (2/863) for the dry and 1.4% (24/1,713) for the wet season, while that of swine was 0.0% (0/159) and 2.0% (7/352) in the two seasons, respectively. Of the 45 RT-PCR positive samples, 13 (28.9%) of them were H5 but none was H7. The 19 swine sera positive for influenza antibodies by ELISA were positive for H1 antibodies by HAI assay, but the subtype(s) of ELISA positive poultry sera could not be determined. Antibodies in the poultry sera could have been those against subtypes not included in the HAI test panel. Conclusions: The study has demonstrated occurrence of influenza A viruses in animals in Uganda. The results suggest that increase in volumes of migratory waterfowl in the country could be associated with increased prevalence of these viruses in free-living waterfowl and poultry.Item Rapid establishment of a frontline field laboratory in response to an imported outbreak of Ebola virus disease in western Uganda, June 2019(PLOS Neglected Tropical Diseases, 2021) Schuh, Amy J.; Kyondo, Jackson; Graziano, James; Balinandi, Stephen; Kainulainen, Markus H.; Tumusiime, Alex; Nyakarahuka, Luke; Mulei, Sophia; Baluku, Jimmy; Lonergan, William; Mayer, Oren; Masereka, Rastus; Masereka, Fredrick; Businge, Esther; Gatare, Alphonse; Kabyanga, Loice; Muhindo, Samuel; Mugabe, Raymond; Makumbi, Issa; Kayiwa, Joshua; Makoba Wetaka, Milton; Brown, Vance; Ojwang, Joseph; Nelson, Lisa; Millard, Monica; Nichol, Stuart T.; Montgomery, Joel M.; Taboy, Celine H.; Lutwama, Julius J.; Klena, John D.The Democratic Republic of the Congo (DRC) declared an Ebola virus disease (EVD) outbreak in North Kivu in August 2018. By June 2019, the outbreak had spread to 26 health zones in northeastern DRC, causing >2,000 reported cases and >1,000 deaths. On June 10, 2019, three members of a Congolese family with EVD-like symptoms traveled to western Uganda’s Kasese District to seek medical care. Shortly thereafter, the Viral Hemorrhagic Fever Surveillance and Laboratory Program (VHF program) at the Uganda Virus Research Institute (UVRI) confirmed that all three patients had EVD. The Ugandan Ministry of Health declared an outbreak of EVD in Uganda’s Kasese District, notified the World Health Organization, and initiated a rapid response to contain the outbreak. As part of this response, UVRI and the United States Centers for Disease Control and Prevention, with the support of Uganda’s Public Health Emergency Operations Center, the Kasese District Health Team, the Superintendent of Bwera General Hospital, the United States Department of Defense’s Makerere University Walter Reed Project, and the United States Mission to Kampala’s Global Health Security Technical Working Group, jointly established an Ebola Field Laboratory in Kasese District at Bwera General Hospital, proximal to an Ebola Treatment Unit (ETU). The laboratory consisted of a rapid containment kit for viral inactivation of patient specimens and a GeneXpert Instrument for performing Xpert Ebola assays. Laboratory staff tested 76 specimens from alert and suspect cases of EVD; the majority were admitted to the ETU (89.3%) and reported recent travel to the DRC (58.9%). Although no EVD cases were detected by the field laboratory, it played an important role in patient management and epidemiological surveillance by providing diagnostic results in <3 hours. The integration of the field laboratory into Uganda’s National VHF Program also enabled patient specimens to be referred to Entebbe for confirmatory EBOV testing and testing for other hemorrhagic fever viruses that circulate in Uganda.Item Seroepidemiological investigation of Crimean Congo hemorrhagic fever virus in livestock in Uganda, 2017.(Public Library of Science, 2023-11) Nyakarahuka, Luke; Kyondo, Jackson; Telford, Carson; Whitesell, Amy; Tumusiime, Alex; Mulei, Sophia; Baluku, Jimmy; Cossaboom, Caitlin M; Cannon, Deborah L; Montgomery, Joel M; Lutwama, Julius J; Nichol, Stuart TAbstract Crimean-Congo Hemorrhagic fever (CCHF) is an important zoonotic disease transmitted to humans both by tick vectors and contact with fluids from an infected animal or human. Although animals are not symptomatic when infected, they are the main source of human infection. Uganda has reported sporadic human outbreaks of CCHF in various parts of the country since 2013. We designed a nationwide epidemiological study to investigate the burden of CCHF in livestock. A total of 3181 animals were sampled; 1732 cattle (54.4%), 1091 goats (34.3%), and 358 sheep (11.3%) resulting in overall livestock seropositivity of IgG antibodies against CCHF virus (CCHFV) of 31.4% (999/3181). Seropositivity in cattle was 16.9% and in sheep and goats was 48.8%. Adult and juvenile animals had higher seropositivity compared to recently born animals, and seropositivity was higher in female animals (33.5%) compared to male animals (24.1%). Local breeds had higher (36.8%) compared to exotic (2.8%) and cross breeds (19.3%). Animals that had a history of abortion or stillbirth had higher seropositivity compared to those without a history of abortion or stillbirth. CCHFV seropositivity appeared to be generally higher in northern districts of the country, though spatial trends among sampled districts were not examined. A multivariate regression analysis using a generalized linear mixed model showed that animal species, age, sex, region, and elevation were all significantly associated with CCHFV seropositivity after adjusting for the effects of other model predictors. This study shows that CCHFV is actively circulating in Uganda, posing a serious risk for human infection. The results from this study can be used to help target surveillance efforts for early case detection in animals and limit subsequent spillover into humans.