Last data update: Jan 13, 2025. (Total: 48570 publications since 2009)
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Crimean-Congo hemorrhagic fever cases diagnosed during an outbreak of Sudan virus disease in Uganda, 2022-23
Balinandi S , Mulei S , Whitmer S , Nyakarahuka L , Cossaboom CM , Shedroff E , Morales-Betoulle M , Krapiunaya I , Tumusiime A , Kyondo J , Baluku J , Namanya D , Torach CR , Mutesi J , Kiconco J , Pimundu G , Muyigi T , Rowland J , Nsawotebba A , Ssewanyana I , Muwanguzi D , Kadobera D , Harris JR , Ario AR , Atek K , Kyobe HB , Nabadda S , Kaleebu P , Mwebesa HG , Montgomery JM , Shoemaker TR , Lutwama JJ , Klena JD . PLoS Negl Trop Dis 2024 18 (10) e0012595 BACKGROUND: In September 2022, Uganda experienced an outbreak of Sudan virus disease (SVD), mainly in central Uganda. As a result of enhanced surveillance activities for Ebola disease, samples from several patients with suspected viral hemorrhagic fever (VHF) were sent to the VHF Program at Uganda Virus Research Institute (UVRI), Entebbe, Uganda, and identified with infections caused by other viral etiologies. Herein, we report the epidemiologic and laboratory findings of Crimean-Congo hemorrhagic fever (CCHF) cases that were detected during the SVD outbreak response. METHODOLOGY: Whole blood samples from VHF suspected cases were tested for Sudan virus (SUDV) by real-time reverse transcription-polymerase chain reaction (RT-PCR); and if negative, were tested for CCHF virus (CCHFV) by RT-PCR. CCHFV genomic sequences generated by metagenomic next generation sequencing were analyzed to ascertain strain relationships. PRINCIPAL FINDINGS: Between September 2022 and January 2023, a total of 2,626 samples were submitted for VHF testing at UVRI. Overall, 13 CCHF cases (including 7 deaths; case fatality rate of 53.8%), aged 4 to 60 years, were identified from 10 districts, including several districts affected by the SVD outbreak. Four cases were identified within the Ebola Treatment Unit (ETU) at Mubende Hospital. Most CCHF cases were males engaged in livestock farming or had exposure to wildlife (n = 8; 61.5%). Among confirmed cases, the most common clinical symptoms were hemorrhage (n = 12; 92.3%), fever (n = 11; 84.6%), anorexia (n = 10; 76.9%), fatigue (n = 9; 69.2%), abdominal pain (n = 9; 69.2%) and vomiting (n = 9; 69.2%). Sequencing analysis showed that the majority of identified CCHFV strains belonged to the Africa II clade previously identified in Uganda. Two samples, however, were identified with greater similarity to a CCHFV strain that was last reported in Uganda in 1958, suggesting possible reemergence. CONCLUSIONS/SIGNIFICANCE: Identifying CCHFV from individuals initially suspected to be infected with SUDV emphasizes the need for comprehensive VHF testing during filovirus outbreak responses in VHF endemic countries. Without expanded testing, CCHFV-infected patients would have posed a risk to health care workers and others while receiving treatment after a negative filovirus diagnosis, thereby complicating response dynamics. Additionally, CCHFV-infected cases could acquire an Ebola infection while in the ETU, and upon release because of a negative Ebola virus result, have the potential to spread these infections in the community. |
Sudan Virus Disease among health care workers, Uganda, 2022
Wailagala A , Blair PW , Kobba K , Mubaraka K , Aanyu-Tumukahebwa H , Kiiza D , Sekikongo MT , Klena JD , Waitt P , Bahatungire RR , Kyobe HS , Atwine D , Adaku A , Bongomin B , Kirenga B , Boore A , Clark DV , Kaggwa D , Gregory M , Kabweru W , Kayondo W , Mbabazi SK , Kibuuka H , Kimuli I , Mulei S , Mutegeki M , Emmanuel B , Mwebesa H , Naluyima P , Okello S , Tumusiime A , Montgomery J , Vasireddy V , Olaro C , Wayengera M , Lamorde M . N Engl J Med 2024 391 (3) 285-287 |
Knowledge, attitudes, and practices and long-term immune response after rVSVΔG-ZEBOV-GP Ebola vaccination in healthcare workers in high-risk districts in Uganda
Waltenburg MA , Kainulainen MH , Whitesell A , Nyakarahuka L , Baluku J , Kyondo J , Twongyeirwe S , Harmon J , Mulei S , Tumusiime A , Bergeron E , Haberling DL , Klena JD , Spiropoulou C , Montgomery JM , Lutwama JJ , Makumbi I , Driwale A , Muruta A , Balinandi S , Shoemaker T , Cossaboom CM . Vaccine 2024 BACKGROUND: The rVSVΔG-ZEBOV-GP Ebola vaccine (rVSV-ZEBOV) has been used in response to Ebola disease outbreaks caused by Ebola virus (EBOV). Understanding Ebola knowledge, attitudes, and practices (KAP) and the long-term immune response following rVSV-ZEBOV are critical to inform recommendations on future use. METHODS: We administered surveys and collected blood samples from healthcare workers (HCWs) from seven Ugandan healthcare facilities. Questionnaires collected information on demographic characteristics and KAP related to Ebola and vaccination. IgG ELISA, virus neutralization, and interferon gamma ELISpot measured immunological responses against EBOV glycoprotein (GP). RESULTS: Overall, 37 % (210/565) of HCWs reported receiving any Ebola vaccination. Knowledge that rVSV-ZEBOV only protects against EBOV was low among vaccinated (32 %; 62/192) and unvaccinated (7 %; 14/200) HCWs. Most vaccinated (91 %; 192/210) and unvaccinated (92 %; 326/355) HCWs wanted to receive a booster or initial dose of rVSV-ZEBOV, respectively. Median time from rVSV-ZEBOV vaccination to sample collection was 37.7 months (IQR: 30.5, 38.3). IgG antibodies against EBOV GP were detected in 95 % (61/64) of HCWs with vaccination cards and in 84 % (162/194) of HCWs who reported receiving a vaccination. Geometric mean titer among seropositive vaccinees was 0.066 IU/mL (95 % CI: 0.058-0.076). CONCLUSION: As Uganda has experienced outbreaks of Sudan virus and Bundibugyo virus, for which rVSV-ZEBOV does not protect against, our findings underscore the importance of continued education and risk communication to HCWs on Ebola and other viral hemorrhagic fevers. IgG antibodies against EBOV GP were detected in most vaccinated HCWs in Uganda 2─4 years after vaccination; however, the duration and correlates of protection warrant further investigation. |
Sudan virus disease super-spreading, Uganda, 2022
Komakech A , Whitmer S , Izudi J , Kizito C , Ninsiima M , Ahirirwe SR , Kabami Z , Ario AR , Kadobera D , Kwesiga B , Gidudu S , Migisha R , Makumbi I , Eurien D , Kayiwa J , Bulage L , Gonahasa DN , Kyamwine I , Okello PE , Nansikombi HT , Atuhaire I , Asio A , Elayeete S , Nsubuga EJ , Masanja V , Migamba SM , Mwine P , Nakamya P , Nampeera R , Kwiringira A , Akunzirwe R , Naiga HN , Namubiru SK , Agaba B , Zalwango JF , Zalwango MG , King P , Simbwa BN , Zavuga R , Wanyana MW , Kiggundu T , Oonyu L , Ndyabakira A , Komugisha M , Kibwika B , Ssemanda I , Nuwamanya Y , Kamukama A , Aanyu D , Kizza D , Ayen DO , Mulei S , Balinandi S , Nyakarahuka L , Baluku J , Kyondo J , Tumusiime A , Aliddeki D , Masiira B , Muwanguzi E , Kimuli I , Bulwadda D , Isabirye H , Aujo D , Kasambula A , Okware S , Ochien E , Komakech I , Okot C , Choi M , Cossaboom CM , Eggers C , Klena JD , Osinubi MO , Sadigh KS , Worrell MC , Boore AL , Shoemaker T , Montgomery JM , Nabadda SN , Mwanga M , Muruta AN , Harris JR . BMC Infect Dis 2024 24 (1) 520 BACKGROUND: On 20 September 2022, Uganda declared its fifth Sudan virus disease (SVD) outbreak, culminating in 142 confirmed and 22 probable cases. The reproductive rate (R) of this outbreak was 1.25. We described persons who were exposed to the virus, became infected, and they led to the infection of an unusually high number of cases during the outbreak. METHODS: In this descriptive cross-sectional study, we defined a super-spreader person (SSP) as any person with real-time polymerase chain reaction (RT-PCR) confirmed SVD linked to the infection of ≥ 13 other persons (10-fold the outbreak R). We reviewed illness narratives for SSPs collected through interviews. Whole-genome sequencing was used to support epidemiologic linkages between cases. RESULTS: Two SSPs (Patient A, a 33-year-old male, and Patient B, a 26-year-old male) were identified, and linked to the infection of one probable and 50 confirmed secondary cases. Both SSPs lived in the same parish and were likely infected by a single ill healthcare worker in early October while receiving healthcare. Both sought treatment at multiple health facilities, but neither was ever isolated at an Ebola Treatment Unit (ETU). In total, 18 secondary cases (17 confirmed, one probable), including three deaths (17%), were linked to Patient A; 33 secondary cases (all confirmed), including 14 (42%) deaths, were linked to Patient B. Secondary cases linked to Patient A included family members, neighbours, and contacts at health facilities, including healthcare workers. Those linked to Patient B included healthcare workers, friends, and family members who interacted with him throughout his illness, prayed over him while he was nearing death, or exhumed his body. Intensive community engagement and awareness-building were initiated based on narratives collected about patients A and B; 49 (96%) of the secondary cases were isolated in an ETU, a median of three days after onset. Only nine tertiary cases were linked to the 51 secondary cases. Sequencing suggested plausible direct transmission from the SSPs to 37 of 39 secondary cases with sequence data. CONCLUSION: Extended time in the community while ill, social interactions, cross-district travel for treatment, and religious practices contributed to SVD super-spreading. Intensive community engagement and awareness may have reduced the number of tertiary infections. Intensive follow-up of contacts of case-patients may help reduce the impact of super-spreading events. |
Seroepidemiological investigation of Crimean Congo hemorrhagic fever virus in livestock in Uganda, 2017
Nyakarahuka L , Kyondo J , Telford C , Whitesell A , Tumusiime A , Mulei S , Baluku J , Cossaboom CM , Cannon DL , Montgomery JM , Lutwama JJ , Nichol ST , Balinandi SK , Klena JD , Shoemaker TR . PLoS One 2023 18 (11) e0288587 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. |
Molecular characterization of the 2022 Sudan virus disease outbreak in Uganda
Balinandi S , Whitmer S , Mulei S , Nassuna C , Pimundu G , Muyigi T , Kainulainen M , Shedroff E , Krapiunaya I , Scholte F , Nyakarahuka L , Tumusiime A , Kyondo J , Baluku J , Kiconco J , Harris JR , Ario AR , Kagirita A , Bosa HK , Ssewanyana I , Nabadda S , Mwebesa HG , Aceng JR , Atwine D , Lutwama JJ , Shoemaker TR , Montgomery JM , Kaleebu P , Klena JD . J Virol 2023 97 (10) e0059023 Uganda experienced five Ebola disease outbreaks caused by Bundibugyo virus (n = 1) and Sudan virus (SUDV) (n = 4) from 2000 to 2021. On 20 September 2022, Uganda declared a fifth Sudan virus disease outbreak in the Mubende district, resulting in 142 confirmed and 22 probable cases by the end of the outbreak declaration on 11 January 2023. The earliest identified cases, through retrospective case investigations, had onset in early August 2022. From the 142 confirmed cases, we performed unbiased (Illumina) and SUDV-amplicon-specific (Minion) high-throughput sequencing to obtain 120 SUDV genome-and coding-complete sequences, representing 95.4% (104/109) of SVD-confirmed individuals within a sequence-able range (Ct ≤30) and 10 genome sequences outside of this range and 6 duplicate genome sequences. A comparison of the nucleotide genetic relatedness for the newly emerged Mubende variant indicated that it was most closely related to the Nakisamata SUDV sequence from 2011, represented a likely new zoonotic spillover event, and exhibited an inter- and intra-outbreak substitution rate consistent with previous outbreaks. The most recent common ancestor for the Mubende variant was estimated to have occurred in October and November 2021. The Mubende variant glycoprotein amino acid sequences exhibited 99.7% similarity altogether and a maximum of 96.1% glycoprotein similarity compared to historical SUDV strains from 1976. Integrating the genetic sequence and epidemiological data into the response activities generated a broad overview of the outbreak, allowing for quick fact-checking of epidemiological connections between the identified patients. IMPORTANCE Ebola disease (EBOD) is a public health threat with a high case fatality rate. Most EBOD outbreaks have occurred in remote locations, but the 2013-2016 Western Africa outbreak demonstrated how devastating EBOD can be when it reaches an urban population. Here, the 2022 Sudan virus disease (SVD) outbreak in Mubende District, Uganda, is summarized, and the genetic relatedness of the new variant is evaluated. The Mubende variant exhibited 96% amino acid similarity with historic SUDV sequences from the 1970s and a high degree of conservation throughout the outbreak, which was important for ongoing diagnostics and highly promising for future therapy development. Genetic differences between viruses identified during the Mubende SVD outbreak were linked with epidemiological data to better interpret viral spread and contact tracing chains. This methodology should be used to better integrate discrete epidemiological and sequence data for future viral outbreaks. |
A countrywide seroepidemiological survey of Rift Valley fever in livestock, Uganda, 2017
Nyakarahuka L , Kyondo J , Telford C , Whitesell A , Tumusiime A , Mulei S , Baluku J , Cossaboom CM , Cannon DL , Montgomery JM , Lutwama JJ , Nichol ST , Balinandi S , Klena JD , Shoemaker TR . Am J Trop Med Hyg 2023 109 (3) 548-553 In 2016, an outbreak of Rift Valley fever was reported in the Kabale District in Uganda for the first time in 48 years. Three human cases were confirmed by polymerase chain reaction, and subsequent serological investigations revealed an overall IgG seropositivity of 13% in humans and 13% in animals. In response to this reemergence, we designed a countrywide survey to determine the seropositivity of anti-Rift Valley fever virus (RVFV) IgG antibodies in livestock. Samples were collected from 27 districts and tested for RVFV anti-IgG antibodies. A total of 3,181 livestock samples were tested, of which 54.4% were cattle (1,732 of 3,181), 34.3% were goats (1,091 of 3,181), and 11.3% were sheep (358 of 3,181). Overall RVFV seropositivity was 6.9% (221 of 3,181). Seroprevalence was greater in cattle (10.7%) compared with goats (2.6%) and sheep (2.0%), among females (7.5%) compared with males (5.2%), and among adults (7.6%) compared with juveniles (4.9%) and nurslings (6.4%). Exotic breeds and animals with a history of abortion or stillbirth also had greater odds of RVFV seropositivity. Animals grazed under tethering and paddocking had greater RVFV seropositivity compared with animals that grazed communally, and livestock in the western and eastern regions had the greatest seroprevalence. In a multivariate regression model, animal species (odds ratio [OR], 6.4; 95% CI, 3.5-11.4) and age (OR, 2.3; 95% CI, 1.4-3.6) were associated significantly with RVFV seropositivity. This study could be important in developing risk-based surveillance for early outbreak detection to limit the spread of RVFV in both human and animal populations. |
Detection of sporadic outbreaks of Rift Valley fever in Uganda through the National Viral Hemorrhagic Fever Surveillance System, 2017-2020
Nyakarahuka L , Whitmer S , Klena J , Balinandi S , Talundzic E , Tumusiime A , Kyondo J , Mulei S , Patel K , Baluku J , Akurut G , Namanya D , Kamugisha K , Cossaboom C , Whitesell A , Telford C , Graziano J , Montgomery J , Nichol S , Lutwama J , Shoemaker T . Am J Trop Med Hyg 2023 108 (5) 995-1002 Rift Valley fever (RVF) is a zoonotic disease of public health and economic importance. Uganda has reported sporadic outbreaks of RVF in both humans and animals across the country, especially in the southwestern part of the "cattle corridor" through an established viral hemorrhagic fever surveillance system. We report 52 human cases of laboratory-confirmed RVF from 2017 to 2020. The case fatality rate was 42%. Among those infected, 92% were males and 90% were adults (≥ 18 years). Clinical symptoms were characterized by fever (69%), unexplained bleeding (69%), headache (51%), abdominal pain (49%), and nausea and vomiting (46%). Most of the cases (95%) originated from central and western districts that are part of the cattle corridor of Uganda, where the main risk factor was direct contact with livestock (P = 0.009). Other predictors of RVF positivity were determined to be male gender (P = 0.001) and being a butcher (P = 0.04). Next-generation sequencing identified the predominant Ugandan clade as Kenya-2, observed previously across East Africa. There is need for further investigation and research into the effect and spread of this neglected tropical disease in Uganda and the rest of Africa. Control measures such as promoting vaccination and limiting animal-human transmission could be explored to reduce the impact of RVF in Uganda and globally. |
Crimean-Congo Hemorrhagic Fever Outbreak in Refugee Settlement during COVID-19 Pandemic, Uganda, April 2021.
Nyakarahuka L , Whitmer S , Kyondo J , Mulei S , Cossaboom CM , Telford CT , Tumusiime A , Akurut GG , Namanya D , Kamugisha K , Baluku J , Lutwama J , Balinandi S , Shoemaker T , Klena JD . Emerg Infect Dis 2022 28 (11) 2326-2329 Crimean-Congo hemorrhagic fever (CCHF) was detected in 2 refugees living in a refugee settlement in Kikuube district, Uganda. Investigations revealed a CCHF IgG seroprevalence of 71.3% (37/52) in goats within the refugee settlement. This finding highlights the need for a multisectoral approach to controlling CCHF in humans and animals in Uganda. |
Rift Valley Fever Outbreak during COVID-19 Surge, Uganda, 2021.
Cossaboom CM , Nyakarahuka L , Mulei S , Kyondo J , Tumusiime A , Baluku J , Akurut GG , Namanya D , Kamugisha K , Nansikombi HT , Nyabakira A , Mutesasira S , Whitmer S , Telford C , Lutwama J , Balinandi S , Montgomery J , Klena JD , Shoemaker T . Emerg Infect Dis 2022 28 (11) 2290-2293 Rift Valley fever, endemic or emerging throughout most of Africa, causes considerable risk to human and animal health. We report 7 confirmed Rift Valley fever cases, 1 fatal, in Kiruhura District, Uganda, during 2021. Our findings highlight the importance of continued viral hemorrhagic fever surveillance, despite challenges associated with the COVID-19 pandemic. |
First laboratory confirmation and sequencing of Zaire ebolavirus in Uganda following two independent introductions of cases from the 10th Ebola Outbreak in the Democratic Republic of the Congo, June 2019
Nyakarahuka L , Mulei S , Whitmer S , Jackson K , Tumusiime A , Schuh A , Baluku J , Joyce A , Ocom F , Tusiime JB , Montgomery JM , Balinandi S , Lutwama JJ , Klena JD , Shoemaker TR . PLoS Negl Trop Dis 2022 16 (2) e0010205 Uganda established a domestic Viral Hemorrhagic Fever (VHF) testing capacity in 2010 in response to the increasing occurrence of filovirus outbreaks. In July 2018, the neighboring Democratic Republic of Congo (DRC) experienced its 10th Ebola Virus Disease (EVD) outbreak and for the duration of the outbreak, the Ugandan Ministry of Health (MOH) initiated a national EVD preparedness stance. Almost one year later, on 10th June 2019, three family members who had contracted EVD in the DRC crossed into Uganda to seek medical treatment. Samples were collected from all the suspected cases using internationally established biosafety protocols and submitted for VHF diagnostic testing at Uganda Virus Research Institute. All samples were initially tested by RT-PCR for ebolaviruses, marburgviruses, Rift Valley fever (RVF) virus and Crimean-Congo hemorrhagic fever (CCHF) virus. Four people were identified as being positive for Zaire ebolavirus, marking the first report of Zaire ebolavirus in Uganda. In-country Next Generation Sequencing (NGS) and phylogenetic analysis was performed for the first time in Uganda, confirming the outbreak as imported from DRC at two different time point from different clades. This rapid response by the MoH, UVRI and partners led to the control of the outbreak and prevention of secondary virus transmission. |
Rapid establishment of a frontline field laboratory in response to an imported outbreak of Ebola virus disease in western Uganda, June 2019.
Schuh AJ , Kyondo J , Graziano J , Balinandi S , Kainulainen MH , Tumusiime A , Nyakarahuka L , Mulei S , Baluku J , Lonergan W , Mayer O , Masereka R , Masereka F , Businge E , Gatare A , Kabyanga L , Muhindo S , Mugabe R , Makumbi I , Kayiwa J , Wetaka MM , Brown V , Ojwang J , Nelson L , Millard M , Nichol ST , Montgomery JM , Taboy CH , Lutwama JJ , Klena JD . PLoS Negl Trop Dis 2021 15 (12) e0009967 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. |
Clinical and Molecular Epidemiology of Crimean-Congo Hemorrhagic Fever in Humans in Uganda, 2013-2019.
Balinandi S , Whitmer S , Mulei S , Nyakarahuka L , Tumusiime A , Kyondo J , Baluku J , Mutyaba J , Mugisha L , Malmberg M , Lutwama J , Shoemaker T , Klena J . Am J Trop Med Hyg 2021 106 (1) 88-98 Crimean-Congo Hemorrhagic Fever (CCHF) is endemic in Uganda, yet its epidemiology remains largely uncharacterized. To better understand its occurrence within Uganda, case reports of patients hospitalized with CCHF between 2013 and 2019 were reviewed. Further, genome sequences of CCHF-positive RNA obtained during this period were determined for phylogenetic comparisons. We found that a total of 32 cases (75% males; CFR, 31.2%), aged between 9 to 68 years, were reported during the study period. Most cases were detected during July to December of each outbreak year (81.2%; P < 0.01) and were located along the "cattle corridor" (68.7%, P = 0.03). The most common presenting symptoms were fever (93.8%), hemorrhage (81.3%), headache (78.1%), fatigue (68.8%), vomiting (68.8%), and myalgia (65.6%). In five patients for whom hematological data were available, varied abnormalities were observed including thrombocytopenia, leukopenia, anemia, lymphopenia, lymphocytosis, polycythemia, and microcytosis. About 56.3% (P = 0.47) of patients reported tick bites or exposure to livestock as their potential source of infection. Person-to-person transmission was suspected for two cases. Using unbiased metagenomics, we found that the viral S- and L- segments have remained conserved in Africa 2 clade since the 1950s. In contrast, the M segment split into two geographically interspersed clades; one that belongs to Africa 2 and another that is ancestral to Africa 1 and 2. Overall, this data summarizes information on the history and clinical presentation of human CCHF in Uganda. Importantly, it identifies vulnerable populations as well as temporal and geographic regions in Uganda where surveillance and control interventions could be focused. |
Serological evidence of Rift Valley fever virus infection among domestic ruminant herds in Uganda
Ndumu DB , Bakamutumaho B , Miller E , Nakayima J , Downing R , Balinandi S , Monje F , Tumusiime D , Nanfuka M , Meunier N , Arinaitwe E , Rutebarika C , Kidega E , Kyondo J , Ademun R , Njenga KM , Veas F , Gonzalez JP . BMC Vet Res 2021 17 (1) 157 BACKGROUND: Prior to the first recorded outbreak of Rift Valley fever (RVF) in Uganda, in March 2016, earlier studies done until the 1970's indicated the presence of the RVF virus (RVFV) in the country, without any recorded outbreaks in either man or animals. While severe outbreaks of RVF occurred in the neighboring countries, none were reported in Uganda despite forecasts that placed some parts of Uganda at similar risk. The Ministry of Agriculture, Animal Industry and Fisheries (MAAIF) undertook studies to determine the RVF sero-prevalence in risk prone areas. Three datasets from cattle sheep and goats were obtained; one from retrospective samples collected in 2010-2011 from the northern region; the second from the western region in 2013 while the third was from a cross-sectional survey done in 2016 in the south-western region. Laboratory analysis involved the use of the Enzyme Linked Immunosorbent Assays (ELISA). Data were subjected to descriptive statistical analyses, including non-parametric chi-square tests for comparisons between districts and species in the regions. RESULTS: During the Yellow Fever outbreak investigation of 2010-2011 in the northern region, a total sero-prevalence of 6.7% was obtained for anti RVFV reacting antibodies (IgG and IgM) among the domestic ruminant population. The 2013 sero-survey in the western region showed a prevalence of 18.6% in cattle and 2.3% in small ruminants. The 2016 sero-survey in the districts of Kabale, Kanungu, Kasese, Kisoro and Rubirizi, in the south-western region, had the respective district RVF sero-prevalence of 16.0, 2.1, 0.8, 15.1and 2.7% among the domestic ruminants combined for this region; bovines exhibited the highest cumulative sero-prevalence of 15.2%, compared to 5.3 and 4.0% respectively for sheep and goats per species for the region. CONCLUSIONS: The absence of apparent outbreaks in Uganda, despite neighboring enzootic areas, having minimal restrictions to the exchange of livestock and their products across borders, suggest an unexpected RVF activity in the study areas that needs to be unraveled. Therefore, more in-depth studies are planned to mitigate the risk of an overt RVF outbreak in humans and animals as has occurred in neighboring countries. |
Sporadic outbreaks of Crimean-Congo haemorrhagic fever in Uganda, July 2018-January 2019
Mirembe BB , Musewa A , Kadobera D , Kisaakye E , Birungi D , Eurien D , Nyakarahuka L , Balinandi S , Tumusiime A , Kyondo J , Mulei SM , Baluku J , Kwesiga B , Kabwama SN , Zhu BP , Harris JR , Lutwama JJ , Ario AR . PLoS Negl Trop Dis 2021 15 (3) e0009213 INTRODUCTION: Crimean-Congo haemorrhagic fever (CCHF) is a tick-borne, zoonotic viral disease that causes haemorrhagic symptoms. Despite having eight confirmed outbreaks between 2013 and 2017, all within Uganda's 'cattle corridor', no targeted tick control programs exist in Uganda to prevent disease. During a seven-month-period from July 2018-January 2019, the Ministry of Health confirmed multiple independent CCHF outbreaks. We investigated to identify risk factors and recommend interventions to prevent future outbreaks. METHODS: We defined a confirmed case as sudden onset of fever (≥37.5°C) with ≥4 of the following signs and symptoms: anorexia, vomiting, diarrhoea, headache, abdominal pain, joint pain, or sudden unexplained bleeding in a resident of the affected districts who tested positive for Crimean-Congo haemorrhagic fever virus (CCHFv) by RT-PCR from 1 July 2018-30 January 2019. We reviewed medical records and performed active case-finding. We conducted a case-control study and compared exposures of case-patients with age-, sex-, and sub-county-matched control-persons (1:4). RESULTS: We identified 14 confirmed cases (64% males) with five deaths (case-fatality rate: 36%) from 11 districts in western and central region. Of these, eight (73%) case-patients resided in Uganda's 'cattle corridor'. One outbreak involved two case-patients and the remainder involved one. All case-patients had fever and 93% had unexplained bleeding. Case-patients were aged 6-36 years, with persons aged 20-44 years more affected (AR: 7.2/1,000,000) than persons ≤19 years (2.0/1,000,000), p = 0.015. Most (93%) case-patients had contact with livestock ≤2 weeks before symptom onset. Twelve (86%) lived <1 km from grazing fields compared with 27 (48%) controls (ORM-H = 18, 95% CI = 3.2-∞) and 10 (71%) of 14 case-patients found ticks attached to their bodies ≤2 weeks before symptom onset, compared to 15 (27%) of 56 control-persons (ORM-H = 9.3, 95%CI = 1.9-46). CONCLUSIONS: CCHF outbreaks occurred sporadically during 2018-2019, both within and outside 'cattle corridor' districts of Uganda. Most cases were associated with tick exposure. The Ministry of Health should partner with the Ministry of Agriculture, Animal Industry and Fisheries to develop joint nationwide tick control programs and strategies with shared responsibilities through a One Health approach. |
Outbreak of anthrax associated with handling and eating meat from a cow, Uganda, 2018
Kisaakye E , Ario AR , Bainomugisha K , Cossaboom CM , Lowe D , Bulage L , Kadobera D , Sekamatte M , Lubwama B , Tumusiime D , Tusiime P , Downing R , Buule J , Lutwama J , Salzer JS , Matkovic E , Ritter J , Gary J , Zhu BP . Emerg Infect Dis 2020 26 (12) 2799-2806 On April 20, 2018, the Kween District Health Office in Kween District, Uganda reported 7 suspected cases of human anthrax. A team from the Uganda Ministry of Health and partners investigated and identified 49 cases, 3 confirmed and 46 suspected; no deaths were reported. Multiple exposures from handling the carcass of a cow that had died suddenly were significantly associated with cutaneous anthrax, whereas eating meat from that cow was associated with gastrointestinal anthrax. Eating undercooked meat was significantly associated with gastrointestinal anthrax, but boiling the meat for >60 minutes was protective. We recommended providing postexposure antimicrobial prophylaxis for all exposed persons, vaccinating healthy livestock in the area, educating farmers to safely dispose of animal carcasses, and avoiding handling or eating meat from livestock that died of unknown causes. |
A retrospective cohort investigation of seroprevalence of Marburg virus and ebolaviruses in two different ecological zones in Uganda
Nyakarahuka L , Schafer IJ , Balinandi S , Mulei S , Tumusiime A , Kyondo J , Knust B , Lutwama J , Rollin P , Nichol S , Shoemaker T . BMC Infect Dis 2020 20 (1) 461 BACKGROUND: Uganda has experienced seven Ebola Virus Disease (EVD) outbreaks and four Marburg Virus Disease (MVD) outbreaks between 2000 and 2019. We investigated the seroprevalence and risk factors for Marburg virus and ebolaviruses in gold mining communities around Kitaka gold mine in Western Uganda and compared them to non-mining communities in Central Uganda. METHODS: A questionnaire was administered and human blood samples were collected from three exposure groups in Western Uganda (gold miners, household members of miners, non-miners living within 50 km of Kitaka mine). The unexposed controls group sampled was community members in Central Uganda far away from any gold mining activity which we considered as low-risk for filovirus infection. ELISA serology was used to analyse samples, detecting IgG antibodies against Marburg virus and ebolaviruses (filoviruses). Data were analysed in STATA software using risk ratios and odds ratios. RESULTS: Miners in western Uganda were 5.4 times more likely to be filovirus seropositive compared to the control group in central Uganda (RR = 5.4; 95% CI 1.5-19.7) whereas people living in high-risk areas in Ibanda and Kamwenge districts were 3.6 more likely to be seropositive compared to control group in Luweeero district (RR = 3.6; 95% CI 1.1-12.2). Among all participants, filovirus seropositivity was 2.6% (19/724) of which 2.3% (17/724) were reactive to Sudan virus only and 0.1% (1/724) to Marburg virus. One individual seropositive for Sudan virus also had IgG antibodies reactive to Bundibugyo virus. The risk factors for filovirus seropositivity identified included mining (AOR = 3.4; 95% CI 1.3-8.5), male sex (AOR = 3.1; 95% CI 1.01-9.5), going inside mines (AOR = 3.1; 95% CI 1.2-8.2), cleaning corpses (AOR = 3.1; 95% CI 1.04-9.1) and contact with suspect filovirus cases (AOR = 3.9, 95% CI 1.04-14.5). CONCLUSIONS: These findings indicate that filovirus outbreaks may go undetected in Uganda and people involved in artisan gold mining are more likely to be exposed to infection with either Marburg virus or ebolaviruses, likely due to increased risk of exposure to bats. This calls for active surveillance in known high-risk areas for early detection and response to prevent filovirus epidemics. |
Uganda's experience in Ebola virus disease outbreak preparedness, 2018-2019
Aceng JR , Ario AR , Muruta AN , Makumbi I , Nanyunja M , Komakech I , Bakainaga AN , Talisuna AO , Mwesigye C , Mpairwe AM , Tusiime JB , Lali WZ , Katushabe E , Ocom F , Kaggwa M , Bongomin B , Kasule H , Mwoga JN , Sensasi B , Mwebembezi E , Katureebe C , Sentumbwe O , Nalwadda R , Mbaka P , Fatunmbi BS , Nakiire L , Lamorde M , Walwema R , Kambugu A , Nanyondo J , Okware S , Ahabwe PB , Nabukenya I , Kayiwa J , Wetaka MM , Kyazze S , Kwesiga B , Kadobera D , Bulage L , Nanziri C , Monje F , Aliddeki DM , Ntono V , Gonahasa D , Nabatanzi S , Nsereko G , Nakinsige A , Mabumba E , Lubwama B , Sekamatte M , Kibuule M , Muwanguzi D , Amone J , Upenytho GD , Driwale A , Seru M , Sebisubi F , Akello H , Kabanda R , Mutengeki DK , Bakyaita T , Serwanjja VN , Okwi R , Okiria J , Ainebyoona E , Opar BT , Mimbe D , Kyabaggu D , Ayebazibwe C , Sentumbwe J , Mwanja M , Ndumu DB , Bwogi J , Balinandi S , Nyakarahuka L , Tumusiime A , Kyondo J , Mulei S , Lutwama J , Kaleebu P , Kagirita A , Nabadda S , Oumo P , Lukwago R , Kasozi J , Masylukov O , Kyobe HB , Berdaga V , Lwanga M , Opio JC , Matseketse D , Eyul J , Oteba MO , Bukirwa H , Bulya N , Masiira B , Kihembo C , Ohuabunwo C , Antara SN , Owembabazi W , Okot PB , Okwera J , Amoros I , Kajja V , Mukunda BS , Sorela I , Adams G , Shoemaker T , Klena JD , Taboy CH , Ward SE , Merrill RD , Carter RJ , Harris JR , Banage F , Nsibambi T , Ojwang J , Kasule JN , Stowell DF , Brown VR , Zhu BP , Homsy J , Nelson LJ , Tusiime PK , Olaro C , Mwebesa HG , Woldemariam YT . Global Health 2020 16 (1) 24 BACKGROUND: Since the declaration of the 10th Ebola Virus Disease (EVD) outbreak in DRC on 1st Aug 2018, several neighboring countries have been developing and implementing preparedness efforts to prevent EVD cross-border transmission to enable timely detection, investigation, and response in the event of a confirmed EVD outbreak in the country. We describe Uganda's experience in EVD preparedness. RESULTS: On 4 August 2018, the Uganda Ministry of Health (MoH) activated the Public Health Emergency Operations Centre (PHEOC) and the National Task Force (NTF) for public health emergencies to plan, guide, and coordinate EVD preparedness in the country. The NTF selected an Incident Management Team (IMT), constituting a National Rapid Response Team (NRRT) that supported activation of the District Task Forces (DTFs) and District Rapid Response Teams (DRRTs) that jointly assessed levels of preparedness in 30 designated high-risk districts representing category 1 (20 districts) and category 2 (10 districts). The MoH, with technical guidance from the World Health Organisation (WHO), led EVD preparedness activities and worked together with other ministries and partner organisations to enhance community-based surveillance systems, develop and disseminate risk communication messages, engage communities, reinforce EVD screening and infection prevention measures at Points of Entry (PoEs) and in high-risk health facilities, construct and equip EVD isolation and treatment units, and establish coordination and procurement mechanisms. CONCLUSION: As of 31 May 2019, there was no confirmed case of EVD as Uganda has continued to make significant and verifiable progress in EVD preparedness. There is a need to sustain these efforts, not only in EVD preparedness but also across the entire spectrum of a multi-hazard framework. These efforts strengthen country capacity and compel the country to avail resources for preparedness and management of incidents at the source while effectively cutting costs of using a "fire-fighting" approach during public health emergencies. |
Marburg virus disease outbreak in Kween District Uganda, 2017: Epidemiological and laboratory findings
Nyakarahuka L , Shoemaker TR , Balinandi S , Chemos G , Kwesiga B , Mulei S , Kyondo J , Tumusiime A , Kofman A , Masiira B , Whitmer S , Brown S , Cannon D , Chiang CF , Graziano J , Morales-Betoulle M , Patel K , Zufan S , Komakech I , Natseri N , Chepkwurui PM , Lubwama B , Okiria J , Kayiwa J , Nkonwa IH , Eyu P , Nakiire L , Okarikod EC , Cheptoyek L , Wangila BE , Wanje M , Tusiime P , Bulage L , Mwebesa HG , Ario AR , Makumbi I , Nakinsige A , Muruta A , Nanyunja M , Homsy J , Zhu BP , Nelson L , Kaleebu P , Rollin PE , Nichol ST , Klena JD , Lutwama JJ . PLoS Negl Trop Dis 2019 13 (3) e0007257 INTRODUCTION: In October 2017, a blood sample from a resident of Kween District, Eastern Uganda, tested positive for Marburg virus. Within 24 hour of confirmation, a rapid outbreak response was initiated. Here, we present results of epidemiological and laboratory investigations. METHODS: A district task force was activated consisting of specialised teams to conduct case finding, case management and isolation, contact listing and follow up, sample collection and testing, and community engagement. An ecological investigation was also carried out to identify the potential source of infection. Virus isolation and Next Generation sequencing were performed to identify the strain of Marburg virus. RESULTS: Seventy individuals (34 MVD suspected cases and 36 close contacts of confirmed cases) were epidemiologically investigated, with blood samples tested for MVD. Only four cases met the MVD case definition; one was categorized as a probable case while the other three were confirmed cases. A total of 299 contacts were identified; during follow- up, two were confirmed as MVD. Of the four confirmed and probable MVD cases, three died, yielding a case fatality rate of 75%. All four cases belonged to a single family and 50% (2/4) of the MVD cases were female. All confirmed cases had clinical symptoms of fever, vomiting, abdominal pain and bleeding from body orifices. Viral sequences indicated that the Marburg virus strain responsible for this outbreak was closely related to virus strains previously shown to be circulating in Uganda. CONCLUSION: This outbreak of MVD occurred as a family cluster with no additional transmission outside of the four related cases. Rapid case detection, prompt laboratory testing at the Uganda National VHF Reference Laboratory and presence of pre-trained, well-prepared national and district rapid response teams facilitated the containment and control of this outbreak within one month, preventing nationwide and global transmission of the disease. |
First Laboratory-Confirmed Outbreak of Human and Animal Rift Valley Fever Virus in Uganda in 48 Years.
Shoemaker TR , Nyakarahuka L , Balinandi S , Ojwang J , Tumusiime A , Mulei S , Kyondo J , Lubwama B , Sekematte M , Namutebi A , Tusiime P , Monje F , Mayanja M , Ssendagire S , Dahlke M , Kyazze S , Wetaka M , Makumbi I , Borchert J , Zufan S , Patel K , Whitmer S , Brown S , Davis WG , Klena JD , Nichol ST , Rollin PE , Lutwama J . Am J Trop Med Hyg 2019 100 (3) 659-671 In 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 10(th) independent viral hemorrhagic fever outbreak to be confirmed in Uganda since 2010. |
Notes from the Field: Crimean-Congo hemorrhagic fever outbreak - Central Uganda, August-September 2017
Kizito S , Okello PE , Kwesiga B , Nyakarahuka L , Balinandi S , Mulei S , Kyondo J , Tumusiime A , Lutwama J , Ario AR , Ojwang J , Zhu BP . MMWR Morb Mortal Wkly Rep 2018 67 (22) 646-647 On August 20, 2017, physicians in two noncontiguous districts in central Uganda (Kyankwanzi and Nakaseke) reported two unrelated cases of Crimean-Congo hemorrhagic fever (CCHF). CCHF is the most widespread tickborne viral hemorrhagic fever in the world and represents a global health security threat (1–3); a single case of CCHF constitutes an outbreak. Humans are infected through tick bites or contact with the blood or body fluids of infected persons or animals. Treatment of infected patients is supportive, and the case-fatality rate ranges from 3%–40% (2,3). No licensed vaccine is available (2). Although CCHF cases were first reported in Uganda between 1958 and 1977, no subsequent cases were reported until 2013, when enhanced viral hemorrhagic fever surveillance capacity began to identify CCHF outbreaks (3–5). |
Rift valley fever viral load correlates with the human inflammatory response and coagulation pathway abnormalities in humans with hemorrhagic manifestations
de St Maurice A , Harmon J , Nyakarahuka L , Balinandi S , Tumusiime A , Kyondo J , Mulei S , Namutebi A , Knust B , Shoemaker T , Nichol ST , McElroy AK , Spiropoulou CF . PLoS Negl Trop Dis 2018 12 (5) e0006460 Rift Valley fever virus is an arbovirus that affects both livestock and humans throughout Africa and in the Middle East. Despite its endemicity throughout Africa, it is a rare event to identify an infected individual during the acute phase of the disease and an even rarer event to collect serial blood samples from the affected patient. Severely affected patients can present with hemorrhagic manifestations of disease. In this study we identified three Ugandan men with RVFV disease that was accompanied by hemorrhagic manifestations. Serial blood samples from these men were analyzed for a series of biomarkers specific for various aspects of human pathophysiology including inflammation, endothelial function and coagulopathy. There were significant differences between biomarker levels in controls and cases both early during the illness and after clearance of viremia. Positive correlation of viral load with markers of inflammation (IP-10, CRP, Eotaxin, MCP-2 and Granzyme B), markers of fibrinolysis (tPA and D-dimer), and markers of endothelial function (sICAM-1) were all noted. However, and perhaps most interesting given the fact that these individuals exhibited hemorrhagic manifestations of disease, was the finding of a negative correlation between viral load and P-selectin, ADAMTS13, and fibrinogen all of which are associated with coagulation pathways occurring on the endothelial surface. |
Prevalence and risk factors of Rift Valley fever in humans and animals from Kabale district in Southwestern Uganda, 2016
Nyakarahuka L , de St Maurice A , Purpura L , Ervin E , Balinandi S , Tumusiime A , Kyondo J , Mulei S , Tusiime P , Lutwama J , Klena J , Brown S , Knust B , Rollin PE , Nichol ST , Shoemaker TR . PLoS Negl Trop Dis 2018 12 (5) e0006412 BACKGROUND: Rift Valley fever (RVF) is a zoonotic disease caused by Rift Valley fever virus (RVFV) found in Africa and the Middle East. Outbreaks can cause extensive morbidity and mortality in humans and livestock. Following the diagnosis of two acute human RVF cases in Kabale district, Uganda, we conducted a serosurvey to estimate RVFV seroprevalence in humans and livestock and to identify associated risk factors. METHODS: Humans and animals at abattoirs and villages in Kabale district were sampled. Persons were interviewed about RVFV exposure risk factors. Human blood was tested for anti-RVFV IgM and IgG, and animal blood for anti-RVFV IgG. PRINCIPAL FINDINGS: 655 human and 1051 animal blood samples were collected. Anti-RVFV IgG was detected in 78 (12%) human samples; 3 human samples (0.5%) had detectable IgM only, and 7 (1%) had both IgM and IgG. Of the 10 IgM-positive persons, 2 samples were positive for RVFV by PCR, confirming recent infection. Odds of RVFV seropositivity were greater in participants who were butchers (odds ratio [OR] 5.1; 95% confidence interval [95% CI]: 1.7-15.1) and those who reported handling raw meat (OR 3.4; 95% CI 1.2-9.8). No persons under age 20 were RVFV seropositive. The overall animal seropositivity was 13%, with 27% of cattle, 7% of goats, and 4% of sheep seropositive. In a multivariate logistic regression, cattle species (OR 9.1; 95% CI 4.1-20.5), adult age (OR 3.0; 95% CI 1.6-5.6), and female sex (OR 2.1; 95%CI 1.0-4.3) were significantly associated with animal seropositivity. Individual human seropositivity was significantly associated with animal seropositivity by subcounty after adjusting for sex, age, and occupation (p < 0.05). CONCLUSIONS: Although no RVF cases had been detected in Uganda from 1968 to March 2016, our study suggests that RVFV has been circulating undetected in both humans and animals living in and around Kabale district. RVFV seropositivity in humans was associated with occupation, suggesting that the primary mode of RVFV transmission to humans in Kabale district could be through contact with animal blood or body fluids. |
Impact of enhanced viral haemorrhagic fever surveillance on outbreak detection and response in Uganda
Shoemaker TR , Balinandi S , Tumusiime A , Nyakarahuka L , Lutwama J , Mbidde E , Kofman A , Klena JD , Stroher U , Rollin PE , Nichol ST . Lancet Infect Dis 2018 18 (4) 373-375 The recent outbreak of Marburg virus disease in Kween District, eastern Uganda, reported in The Lancet Infectious Diseases,1 marks the 13th independent viral haemorrhagic fever outbreak identified and confirmed via laboratory test by the Uganda Virus Research Institute (UVRI)’s viral haemorrhagic fever surveillance and laboratory programme since 2010. This Marburg virus disease outbreak was followed closely by three independent confirmations of human Rift Valley fever virus infection in three districts in central Uganda, and now brings the total viral haemorrhagic fever outbreak detections to 16. This exceptional number of early detections and subsequent outbreak responses has led to a significant decrease in the overall intensity (p=0·001) and duration (p<0·0001) of viral haemorrhagic fever outbreaks in Uganda, and serves as a role model for detecting and responding to public health threats of international concern. |
Rift Valley Fever: A survey of knowledge, attitudes, and practice of slaughterhouse workers and community members in Kabale District, Uganda
de St Maurice A , Nyakarahuka L , Purpura L , Ervin E , Tumusiime A , Balinandi S , Kyondo J , Mulei S , Tusiime P , Manning C , Rollin PE , Knust B , Shoemaker T . PLoS Negl Trop Dis 2018 12 (3) e0006175 BACKGROUND: Rift Valley Fever virus (RVF) is a zoonotic virus in the Phenuiviridae family. RVF outbreaks can cause significant morbidity and mortality in humans and animals. Following the diagnosis of two RVF cases in March 2016 in southern Kabale district, Uganda, we conducted a knowledge, attitudes and practice (KAP) survey to identify knowledge gaps and at-risk behaviors related to RVF. METHODOLOGY/PRINCIPAL FINDINGS: A multidisciplinary team interviewed 657 community members, including abattoir workers, in and around Kabale District, Uganda. Most participants (90%) had knowledge of RVF and most (77%) cited radio as their primary information source. Greater proportions of farmers (68%), herdsmen (79%) and butchers (88%) thought they were at risk of contracting RVF compared to persons in other occupations (60%, p<0.01). Participants most frequently identified bleeding as a symptom of RVF. Less than half of all participants reported fever, vomiting, and diarrhea as common RVF symptoms in either humans or animals. The level of knowledge about human RVF symptoms did not vary by occupation; however more farmers and butchers (36% and 51%, respectively) had knowledge of RVF symptoms in animals compared to those in other occupations (30%, p<0.01). The use of personal protective equipment (PPE) when handling animals varied by occupation, with 77% of butchers using some PPE and 12% of farmers using PPE. Although most butchers said that they used PPE, most used gumboots (73%) and aprons (60%) and less than 20% of butchers used gloves or eye protection when slaughtering. CONCLUSIONS: Overall, knowledge, attitudes and practice regarding RVF in Kabale District Uganda could be improved through educational efforts targeting specific populations. |
Investigation of an isolated case of human Crimean-Congo hemorrhagic fever in Central Uganda, 2015.
Balinandi S , Patel K , Ojwang J , Kyondo J , Mulei S , Tumusiime A , Lubwama B , Nyakarahuka L , Klena J , Lutwama J , Stroher U , Nichol ST , Shoemaker T . Int J Infect Dis 2018 68 88-93 BACKGROUND: Crimean-Congo hemorrhagic fever (CCHF) is the most geographically widespread tick-borne viral infection. Outbreaks of CCHF in sub-Saharan Africa are largely undetected and thus under-reported. On November 9, 2015, the National Viral Hemorrhagic Fever Laboratory at the Uganda Virus Research Institute received an alert for a suspect VHF case in a 33-year-old male who presented with VHF compatible signs and symptoms at Mengo Hospital in Kampala. METHODS: A blood sample from the suspect patient was tested by RT-PCR for CCHF and found positive. Serological testing on sequential blood specimens collected from this patient showed increasing anti-CCHFV IgM antibody titers, confirming recent infection. Repeat sampling of the confirmed case post recovery showed high titers for anti-CCHFV-specific IgG. An epidemiological outbreak investigation was initiated following the initial RT-PCR positive detection to identify any additional suspect cases. RESULTS: Only a single acute case of CCHF was detected from this outbreak. No additional acute CCHF cases were identified following field investigations. Environmental investigations collected 53 tick samples, with only 1, a Boophilus decoloratus, having detectable CCHFV RNA by RT-PCR. Full-length genomic sequencing on a viral isolate from the index human case showed the virus to be related to the DRC (Africa 2) lineage. CONCLUSIONS: This is the fourth confirmed CCHF outbreak in Uganda within 2 years after more than 50 years of no reported human CCHF cases in this country. Our investigations reaffirm the endemicity of CCHFV in Uganda, and shows that exposure to ticks poses a significant risk for human infection. These findings also reflect the importance of having an established national VHF surveillance system and diagnostic capacity in a developing country like Uganda, in order to identify the first cases of VHF outbreaks and rapidly respond to reduce secondary cases. Additional efforts should focus on implementing effective tick control methods and investigating the circulation of CCHFV throughout the country. |
Isolated case of Marburg virus disease, Kampala, Uganda, 2014
Nyakarahuka L , Ojwang J , Tumusiime A , Balinandi S , Whitmer S , Kyazze S , Kasozi S , Wetaka M , Makumbi I , Dahlke M , Borchert J , Lutwama J , Stroher U , Rollin PE , Nichol ST , Shoemaker TR . Emerg Infect Dis 2017 23 (6) 1001-1004 In September 2014, a single fatal case of Marburg virus was identified in a healthcare worker in Kampala, Uganda. The source of infection was not identified, and no secondary cases were identified. We describe the rapid identification, laboratory diagnosis, and case investigation of the third Marburg virus outbreak in Uganda. |
Notes from the Field: Rift Valley Fever Response - Kabale District, Uganda, March 2016
de St Maurice A , Nyakarahuka L , Purpura L , Ervin E , Tumusiime A , Balinandi S , Kayondo J , Mulei S , Namutebi AM , Tusiime P , Wiersma S , Nichol S , Rollin P , Klena J , Knust B , Shoemaker T . MMWR Morb Mortal Wkly Rep 2016 65 (43) 1200-1201 On March 9, 2016, a male butcher from Kabale District, Uganda, aged 45 years, reported to the Kabale Regional Referral Hospital with fever, fatigue, and headache associated with black tarry stools and bleeding from the nose. One day later, a student aged 16 years from a different sub-county in Kabale District developed similar symptoms and was admitted to the same hospital. The student also had a history of contact with livestock. Blood specimens collected from both patients were sent for testing for Marburg virus disease, Ebola virus disease, Rift Valley fever (RVF), and Crimean Congo Hemorrhagic fever at the Uganda Virus Research Institute, as part of the viral hemorrhagic fevers surveillance program. The Uganda Virus Research Institute serves as the national viral hemorrhagic fever reference laboratory and hosts the national surveillance program for viral hemorrhagic fevers, in collaboration with the CDC Viral Special Pathogens Branch and the Uganda Ministry of Health. |
Multidistrict outbreak of Marburg virus disease - Uganda, 2012
Knust B , Schafer IJ , Wamala J , Nyakarahuka L , Okot C , Shoemaker T , Dodd K , Gibbons A , Balinandi S , Tumusiime A , Campbell S , Newman E , Lasry E , DeClerck H , Boum Y , Makumbi I , Bosa HK , Mbonye A , Aceng JR , Nichol ST , Stroher U , Rollin PE . J Infect Dis 2015 212 Suppl 2 S119-28 In October 2012, a cluster of illnesses and deaths was reported in Uganda and was confirmed to be an outbreak of Marburg virus disease (MVD). Patients meeting the case criteria were interviewed using a standard investigation form, and blood specimens were tested for evidence of acute or recent Marburg virus infection by reverse transcription-polymerase chain reaction (RT-PCR) and antibody enzyme-linked immunosorbent assay. The total count of confirmed and probable MVD cases was 26, of which 15 (58%) were fatal. Four of 15 laboratory-confirmed cases (27%) were fatal. Case patients were located in 4 different districts in Uganda, although all chains of transmission originated in Ibanda District, and the earliest case detected had an onset in July 2012. No zoonotic exposures were identified. Symptoms significantly associated with being a MVD case included hiccups, anorexia, fatigue, vomiting, sore throat, and difficulty swallowing. Contact with a case patient and attending a funeral were also significantly associated with being a case. Average RT-PCR cycle threshold values for fatal cases during the acute phase of illness were significantly lower than those for nonfatal cases. Following the institution of contact tracing, active case surveillance, care of patients with isolation precautions, community mobilization, and rapid diagnostic testing, the outbreak was successfully contained 14 days after its initial detection. |
Genomic analysis of filoviruses associated with four viral hemorrhagic fever outbreaks in Uganda and the Democratic Republic of the Congo in 2012.
Albarino CG , Shoemaker T , Khristova ML , Wamala JF , Muyembe JJ , Balinandi S , Tumusiime A , Campbell S , Cannon D , Gibbons A , Bergeron E , Bird B , Dodd K , Spiropoulou C , Erickson BR , Guerrero L , Knust B , Nichol ST , Rollin PE , Stroher U . Virology 2013 442 (2) 97-100 In 2012, an unprecedented number of four distinct, partially overlapping filovirus-associated viral hemorrhagic fever outbreaks were detected in equatorial Africa. Analysis of complete virus genome sequences confirmed the reemergence of Sudan virus and Marburg virus in Uganda, and the first emergence of Bundibugyo virus in the Democratic Republic of the Congo. |
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