Last data update: Dec 02, 2024. (Total: 48272 publications since 2009)
Records 1-6 (of 6 Records) |
Query Trace: Zufan S[original query] |
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Human Orthohantavirus disease prevalence and genotype distribution in the U.S., 2008–2020: a retrospective observational study
Whitmer SLM , Whitesell A , Mobley M , Talundzic E , Shedroff E , Cossaboom CM , Messenger S , Deldari M , Bhatnagar J , Estetter L , Zufan S , Cannon D , Chiang CF , Gibbons A , Krapiunaya I , Morales-Betoulle M , Choi M , Knust B , Amman B , Montgomery JM , Shoemaker T , Klena JD . Lancet Reg Health - Am 2024 37 Background: In the United States (U.S.), hantavirus pulmonary syndrome (HPS) and non-HPS hantavirus infection are nationally notifiable diseases. Criteria for identifying human cases are based on clinical symptoms (HPS or non-HPS) and acute diagnostic results (IgM+, rising IgG+ titers, RT-PCR+, or immunohistochemistry (IHC)+). Here we provide an overview of diagnostic testing and summarize human Hantavirus disease occurrence and genotype distribution in the U.S. from 2008 to 2020. Methods: Epidemiological data from the national hantavirus registry was merged with laboratory diagnostic testing results performed at the CDC. Residual hantavirus-positive specimens were sequenced, and the available epidemiological and genetic data sets were linked to conduct a genomic epidemiological study of hantavirus disease in the U.S. Findings: From 1993 to 2020, 833 human hantavirus cases have been identified, and from 2008 to 2020, 335 human cases have occurred. Among New World (NW) hantavirus cases detected at the CDC diagnostic laboratory (representing 29.2% of total cases), most (85.0%) were detected during acute disease, however, some convalescent cases were detected in states not traditionally associated with hantavirus infections (Connecticut, Missouri, New Jersey, Pennsylvania, Tennessee, and Vermont). From 1993 to 2020, 94.9% (745/785) of U.S. hantaviruses cases were detected west of the Mississippi with 45.7% (359/785) in the Four Corners region of the U.S. From 2008 to 2020, 67.7% of NW hantavirus cases were detected between the months of March and August. Sequencing of RT-PCR-positive cases demonstrates a geographic separation of Orthohantavirus sinnombreense species [Sin Nombre virus (SNV), New York virus, and Monongahela virus]; however, there is a large gap in viral sequence data from the Northwestern and Central U.S. Finally, these data indicate that commercial IgM assays are not concordant with CDC-developed assays, and that “concordant positive” (i.e., commercial IgM+ and CDC IgM+ results) specimens exhibit clinical characteristics of hantavirus disease. Interpretation: Hantaviral disease is broadly distributed in the contiguous U.S, viral variants are localised to specific geographic regions, and hantaviral disease infrequently detected in most Southeastern states. Discordant results between two diagnostic detection methods highlight the need for an improved standardised testing plan in the U.S. Hantavirus surveillance and detection will continue to improve with clearly defined, systematic reporting methods, as well as explicit guidelines for clinical characterization and diagnostic criteria. Funding: This work was funded by core funds provided to the Viral Special Pathogens Branch at CDC. © 2024 |
Inference of Nipah virus evolution, 1999-2015.
Whitmer SLM , Lo MK , Sazzad HMS , Zufan S , Gurley ES , Sultana S , Amman B , Ladner JT , Rahman MZ , Doan S , Satter SM , Flora MS , Montgomery JM , Nichol ST , Spiropoulou CF , Klena JD . Virus Evol 2021 7 (1) veaa062 Despite near-annual human outbreaks of Nipah virus (NiV) disease in Bangladesh, typically due to individual spillover events from the local bat population, only twenty whole-genome NiV sequences exist from humans and ten from bats. NiV whole-genome sequences from annual outbreaks have been challenging to generate, primarily due to the low viral load in human throat swab and serum specimens. Here, we used targeted enrichment with custom NiV-specific probes and generated thirty-five additional unique full-length genomic sequences directly from human specimens and viral isolates. We inferred the temporal and geographic evolutionary history of NiV in Bangladesh and expanded a tool to visualize NiV spatio-temporal spread from a Bayesian continuous diffusion analysis. We observed that strains from Bangladesh segregated into two distinct clades that have intermingled geographically in Bangladesh over time and space. As these clades expanded geographically and temporally, we did not observe evidence for significant branch and site-specific selection, except for a single site in the Henipavirus L polymerase. However, the Bangladesh 1 and 2 clades are differentiated by mutations initially occurring in the polymerase, with additional mutations accumulating in the N, G, F, P, and L genes on external branches. Modeling the historic geographical and temporal spread demonstrates that while widespread, NiV does not exhibit significant genetic variation in Bangladesh. Thus, future public health measures should address whether NiV within in the bat population also exhibits comparable genetic variation, if zoonotic transmission results in a genetic bottleneck and if surveillance techniques are detecting only a subset of NiV. Copyright © 2020 Published by Oxford University Press 2020. This work is written by a US Government employee and is in the public domain in the US. |
Seoul virus infection and spread in US home-based ratteries-rat and human testing results from a multistate outbreak investigation.
Knust B , Brown S , de St Maurice A , Whitmer S , Koske SE , Ervin E , Patel K , Graziano J , Morales-Betoulle ME , House J , Cannon D , Kerins J , Holzbauer S , Austin C , Gibbons-Burgener S , Colton L , Dunn J , Zufan S , Choi MJ , Davis WR , Chiang CF , Manning CR , Roesch L , Shoemaker T , Purpura L , McQuiston J , Peterson D , Radcliffe R , Garvey A , Christel E , Morgan L , Scheftel J , Kazmierczak J , Klena JD , Nichol ST , Rollin PE . J Infect Dis 2020 222 (8) 1311-1319 BACKGROUND: During 2017, a multi-state outbreak investigation occurred following the confirmation of Seoul virus (SEOV) infections in people and pet rats. A total of 147 humans and 897 rats were tested. METHODS: In addition to IgG and IgM serology and traditional RT-PCR, novel quantitative RT-PCR primers/probe were developed, and whole genome sequencing was performed. RESULTS: Seventeen people had SEOV IgM, indicating recent infection; seven reported symptoms and three were hospitalized. All patients recovered. Thirty-one facilities in 11 US states had SEOV infection, and among those with >/=10 rats tested, rat IgG prevalence ranged 2-70% and SEOV RT-PCR positivity ranged 0-70%. Human lab-confirmed cases were significantly associated with rat IgG positivity and RT-PCR positivity (p=0.03 and p=0.006, respectively). Genomic sequencing identified >99.5% homology between SEOV sequences in this outbreak, and these were >99% identical to SEOV associated with previous pet rat infections in England, the Netherlands, and France. Frequent trade of rats between home-based ratteries contributed to transmission of SEOV between facilities. CONCLUSIONS: Pet rat owners, breeders, and the healthcare and public health community should be aware and take steps to prevent SEOV transmission in pet rats and to humans. Biosecurity measures and diagnostic testing can prevent further infections. |
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: Contact tracing investigation after first case of Andes virus in the United States - Delaware, February 2018
Kofman A , Eggers P , Kjemtrup A , Hall R , Brown SM , Morales-Betoulle M , Graziano J , Zufan SE , Whitmer SLM , Cannon DL , Chiang CF , Choi MJ , Rollin PE , Cetron MS , Yaglom HD , Duwell M , Kuhar DT , Kretschmer M , Knust B , Klena JD , Alvarado-Ramy F , Shoemaker T , Towner JS , Nichol ST . MMWR Morb Mortal Wkly Rep 2018 67 (41) 1162-1163 In January 2018, a woman admitted to a Delaware hospital tested positive for New World hantavirus immunoglobulin M (IgM) and immunoglobulin G (IgG) by enzyme-linked immunosorbent assay (ELISA). Subsequent testing by CDC’s Viral Special Pathogens Branch detected New World hantavirus by nested reverse transcription–polymerase chain reaction (RT-PCR) and Andes virus by nucleic acid sequencing. This case represents the first confirmed importation of Andes virus infection into the United States; two imported cases have also been reported in Switzerland (1). Before her illness, the patient had traveled to the Andes region of Argentina and Chile from December 20, 2017, to January 3, 2018. She stayed in cabins and youth hostels in reportedly poor condition. No rodent exposures were reported. After returning to the United States on January 10, she developed fever, malaise, and myalgias on January 14. On January 17, while ill, she traveled on two commercial domestic flights. She was hospitalized during January 20–25 in Delaware and discharged to her home after clinical recovery. |
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