Last data update: Dec 02, 2024. (Total: 48272 publications since 2009)
Records 1-12 (of 12 Records) |
Query Trace: McCollum Andrea M[original query] |
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Ebola Virus Disease Outbreak - Democratic Republic of the Congo, August 2018-November 2019.
Aruna A , Mbala P , Minikulu L , Mukadi D , Bulemfu D , Edidi F , Bulabula J , Tshapenda G , Nsio J , Kitenge R , Mbuyi G , Mwanzembe C , Kombe J , Lubula L , Shako JC , Mossoko M , Mulangu F , Mutombo A , Sana E , Tutu Y , Kabange L , Makengo J , Tshibinkufua F , Ahuka-Mundeke S , Muyembe JJ , Ebola Response CDC , Alarcon Walter , Bonwitt Jesse , Bugli Dante , Bustamante Nirma D , Choi Mary , Dahl Benjamin A , DeCock Kevin , Dismer Amber , Doshi Reena , Dubray Christine , Fitter David , Ghiselli Margherita , Hall Noemi , Hamida Amen Ben , McCollum Andrea M , Neatherlin John , Raghunathan Pratima L , Ravat Fatima , Reynolds Mary G , Rico Adriana , Smith Nailah , Soke Gnakub Norbert , Trudeau Aimee T , Victory Kerton R , Worrell Mary Claire . MMWR Morb Mortal Wkly Rep 2019 68 (50) 1162-1165 On August 1, 2018, the Democratic Republic of the Congo Ministry of Health (DRC MoH) declared the tenth outbreak of Ebola virus disease (Ebola) in DRC, in the North Kivu province in eastern DRC on the border with Uganda, 8 days after another Ebola outbreak was declared over in northwest Équateur province. During mid- to late-July 2018, a cluster of 26 cases of acute hemorrhagic fever, including 20 deaths, was reported in North Kivu province.* Blood specimens from six patients hospitalized in the Mabalako health zone and sent to the Institut National de Recherche Biomédicale (National Biomedical Research Institute) in Kinshasa tested positive for Ebola virus. Genetic sequencing confirmed that the outbreaks in North Kivu and Équateur provinces were unrelated. From North Kivu province, the outbreak spread north to Ituri province, and south to South Kivu province (1). On July 17, 2019, the World Health Organization designated the North Kivu and Ituri outbreak a public health emergency of international concern, based on the geographic spread of the disease to Goma, the capital of North Kivu province, and to Uganda and the challenges to implementing prevention and control measures specific to this region (2). This report describes the outbreak in the North Kivu and Ituri provinces. As of November 17, 2019, a total of 3,296 Ebola cases and 2,196 (67%) deaths were reported, making this the second largest documented outbreak after the 2014-2016 epidemic in West Africa, which resulted in 28,600 cases and 11,325 deaths.(†) Since August 2018, DRC MoH has been collaborating with partners, including the World Health Organization, the United Nations Children's Fund, the United Nations Office for the Coordination of Humanitarian Affairs, the International Organization of Migration, The Alliance for International Medical Action (ALIMA), Médecins Sans Frontières, DRC Red Cross National Society, and CDC, to control the outbreak. Enhanced communication and effective community engagement, timing of interventions during periods of relative stability, and intensive training of local residents to manage response activities with periodic supervision by national and international personnel are needed to end the outbreak. |
Exportation of Monkeypox virus from the African continent.
Mauldin MR , McCollum AM , Nakazawa YJ , Mandra A , Whitehouse ER , Davidson W , Zhao H , Gao J , Li Y , Doty J , Yinka-Ogunleye A , Akinpelu A , Aruna O , Naidoo D , Lewandowski K , Afrough B , Graham V , Aarons E , Hewson R , Vipond R , Dunning J , Chand M , Brown C , Cohen-Gihon I , Erez N , Shifman O , Israeli O , Sharon M , Schwartz E , Beth-Din A , Zvi A , Mak TM , Ng YK , Cui L , Lin RTP , Olson VA , Brooks T , Paran N , Ihekweazu C , Reynolds MG . J Infect Dis 2020 225 (8) 1367-1376 BACKGROUND: The largest West African monkeypox outbreak began September 2017, in Nigeria. Four individuals traveling from Nigeria to the UK (2), Israel, and Singapore became the first human monkeypox cases exported from Africa, and a related nosocomial transmission event in the UK became the first confirmed human-to-human monkeypox transmission event outside of Africa. METHODS: Epidemiological and molecular data for exported and Nigerian cases were analyzed jointly to better understand the exportations in the temporal and geographic context of the outbreak. RESULTS: Isolates from all travelers and a Bayelsa case shared a most recent common ancestor and traveled to Bayelsa, Delta, or Rivers states. Genetic variation for this cluster was lower than would be expected from a random sampling of genomes from this outbreak, but data did not support direct links between travelers. CONCLUSIONS: Monophyly of exportation cases and the Bayelsa sample, along with the intermediate levels of genetic variation suggest a small pool of related isolates is the likely source for the exported infections. This may be the result of the level of genetic variation present in monkeypox isolates circulating within the contiguous region of Bayelsa, Delta, and Rivers states, or another more restricted, yet unidentified source pool. |
The origins and genomic diversity of American Civil War Era smallpox vaccine strains.
Duggan AT , Klunk J , Porter AF , Dhody AN , Hicks R , Smith GL , Humphreys M , McCollum AM , Davidson WB , Wilkins K , Li Y , Burke A , Polasky H , Flanders L , Poinar D , Raphenya AR , Lau TTY , Alcock B , McArthur AG , Golding GB , Holmes EC , Poinar HN . Genome Biol 2020 21 (1) 175 Vaccination has transformed public health, most notably including the eradication of smallpox. Despite its profound historical importance, little is known of the origins and diversity of the viruses used in smallpox vaccination. Prior to the twentieth century, the method, source and origin of smallpox vaccinations remained unstandardised and opaque. We reconstruct and analyse viral vaccine genomes associated with smallpox vaccination from historical artefacts. Significantly, we recover viral molecules through non-destructive sampling of historical materials lacking signs of biological residues. We use the authenticated ancient genomes to reveal the evolutionary relationships of smallpox vaccination viruses within the poxviruses as a whole. |
Human monkeypox - After 40 years, an unintended consequence of smallpox eradication.
Simpson K , Heymann D , Brown CS , Edmunds WJ , Elsgaard J , Fine P , Hochrein H , Hoff NA , Green A , Ihekweazu C , Jones TC , Lule S , Maclennan J , McCollum A , Muhlemann B , Nightingale E , Ogoina D , Ogunleye A , Petersen B , Powell J , Quantick O , Rimoin AW , Ulaeato D , Wapling A . Vaccine 2020 38 (33) 5077-5081 Smallpox eradication, coordinated by the WHO and certified 40 years ago, led to the cessation of routine smallpox vaccination in most countries. It is estimated that over 70% of the world's population is no longer protected against smallpox, and through cross-immunity, to closely related orthopox viruses such as monkeypox. Monkeypox is now a re-emerging disease. Monkeypox is endemic in as yet unconfirmed animal reservoirs in sub-Saharan Africa, while its human epidemiology appears to be changing. Monkeypox in small animals imported from Ghana as exotic pets was at the origin of an outbreak of human monkeypox in the USA in 2003. Travellers infected in Nigeria were at the origin of monkeypox cases in the UK in 2018 and 2019, Israel in 2018 and Singapore in2019. Together with sporadic reports of human infections with other orthopox viruses, these facts invite speculation that emergent or re-emergent human monkeypox might fill the epidemiological niche vacated by smallpox. An ad-hoc and unofficial group of interested experts met to consider these issues at Chatham House, London in June 2019, in order to review available data and identify monkeypox-related research gaps. Gaps identified by the experts included:The experts further agreed on the need for a better understanding of the genomic evolution and changing epidemiology of orthopox viruses, the usefulness of in-field genomic diagnostics, and the best disease control strategies, including the possibility of vaccination with new generation non-replicating smallpox vaccines and treatment with recently developed antivirals. |
Genome of Alaskapox Virus, A Novel Orthopoxvirus Isolated from Alaska.
Gigante CM , Gao J , Tang S , McCollum AM , Wilkins K , Reynolds MG , Davidson W , McLaughlin J , Olson VA , Li Y . Viruses 2019 11 (8) Since the eradication of smallpox, there have been increases in poxvirus infections and the emergence of several novel poxviruses that can infect humans and domestic animals. In 2015, a novel poxvirus was isolated from a resident of Alaska. Diagnostic testing and limited sequence analysis suggested this isolate was a member of the Orthopoxvirus (OPXV) genus but was highly diverged from currently known species, including Akhmeta virus. Here, we present the complete 210,797 bp genome sequence of the Alaska poxvirus isolate, containing 206 predicted open reading frames. Phylogenetic analysis of the conserved central region of the genome suggested the Alaska isolate shares a common ancestor with Old World OPXVs and is diverged from New World OPXVs. We propose this isolate as a member of a new OPXV species, Alaskapox virus (AKPV). The AKPV genome contained host range and virulence genes typical of OPXVs but lacked homologs of C4L and B7R, and the hemagglutinin gene contained a unique 120 amino acid insertion. Seven predicted AKPV proteins were most similar to proteins in non-OPXV Murmansk or NY_014 poxviruses. Genomic analysis revealed evidence suggestive of recombination with Ectromelia virus in two putative regions that contain seven predicted coding sequences, including the A-type inclusion protein. |
Outbreak of human monkeypox in Nigeria in 2017-18: a clinical and epidemiological report.
Yinka-Ogunleye A , Aruna O , Dalhat M , Ogoina D , McCollum A , Disu Y , Mamadu I , Akinpelu A , Ahmad A , Burga J , Ndoreraho A , Nkunzimana E , Manneh L , Mohammed A , Adeoye O , Tom-Aba D , Silenou B , Ipadeola O , Saleh M , Adeyemo A , Nwadiutor I , Aworabhi N , Uke P , John D , Wakama P , Reynolds M , Mauldin MR , Doty J , Wilkins K , Musa J , Khalakdina A , Adedeji A , Mba N , Ojo O , Krause G , Ihekweazu C . Lancet Infect Dis 2019 19 (8) 872-879 BACKGROUND: In September, 2017, human monkeypox re-emerged in Nigeria, 39 years after the last reported case. We aimed to describe the clinical and epidemiological features of the 2017-18 human monkeypox outbreak in Nigeria. METHODS: We reviewed the epidemiological and clinical characteristics of cases of human monkeypox that occurred between Sept 22, 2017, and Sept 16, 2018. Data were collected with a standardised case investigation form, with a case definition of human monkeypox that was based on previously established guidelines. Diagnosis was confirmed by viral identification with real-time PCR and by detection of positive anti-orthopoxvirus IgM antibodies. Whole-genome sequencing was done for seven cases. Haplotype analysis results, genetic distance data, and epidemiological data were used to infer a likely series of events for potential human-to-human transmission of the west African clade of monkeypox virus. FINDINGS: 122 confirmed or probable cases of human monkeypox were recorded in 17 states, including seven deaths (case fatality rate 6%). People infected with monkeypox virus were aged between 2 days and 50 years (median 29 years [IQR 14]), and 84 (69%) were male. All 122 patients had vesiculopustular rash, and fever, pruritus, headache, and lymphadenopathy were also common. The rash affected all parts of the body, with the face being most affected. The distribution of cases and contacts suggested both primary zoonotic and secondary human-to-human transmission. Two cases of health-care-associated infection were recorded. Genomic analysis suggested multiple introductions of the virus and a single introduction along with human-to-human transmission in a prison facility. INTERPRETATION: This study describes the largest documented human outbreak of the west African clade of the monkeypox virus. Our results suggest endemicity of monkeypox virus in Nigeria, with some evidence of human-to-human transmission. Further studies are necessary to explore animal reservoirs and risk factors for transmission of the virus in Nigeria. FUNDING: None. |
Evaluation of the GeneXpert for Human Monkeypox Diagnosis.
Li D , Wilkins K , McCollum AM , Osadebe L , Kabamba J , Nguete B , Likafi T , Balilo MP , Lushima RS , Malekani J , Damon IK , Vickery MC , Pukuta E , Nkawa F , Karhemere S , Tamfum JM , Okitolonda EW , Li Y , Reynolds MG . Am J Trop Med Hyg 2016 96 (2) 405-410 Monkeypox virus (MPXV), a zoonotic orthopoxvirus (OPX), is endemic in the Democratic Republic of Congo (DRC). Currently, diagnostic assays for human monkeypox (MPX) focus on real-time quantitative polymerase chain reaction (qPCR) assays, which are typically performed in sophisticated laboratory settings. Herein, we evaluate the accuracy and utility of a multiplex MPXV assay using the GeneXpert platform, a portable rapid diagnostic device that may serve as a point-of-care test to diagnose infections in endemic areas. The multiplex MPX/OPX assay includes a MPX-specific qPCR test, OPX-generic qPCR test, and an internal control qPCR test. In total, 164 diagnostic specimens (50 crusts and 114 vesicular swabs) were collected from suspected MPX cases in Tshuapa District, DRC, under national surveillance guidelines. The specimens were tested with the GeneXpert MPX/OPX assay and an OPX qPCR assay at the Institut National de Recherche Biomedicale (INRB) in Kinshasa. Aliquots of each specimen were tested in parallel with a q-specific MPX qPCR assay at the Centers for Disease Control and Prevention. The results of the MPX qPCR were used as the gold standard for all analyses. The GeneXpert MPX/OPX assay performed at INRB had a sensitivity of 98.8% and specificity of 100%. The GeneXpert assay performed well with both crust and vesicle samples. The GeneXpert MPX/OPX test incorporates a simple methodology that performs well in both laboratory and field conditions, suggesting its viability as a diagnostic platform that may expand and expedite current MPX detection capabilities. |
Unique Presentation of Orf Virus Infection in a Thermal Burn Patient After Receiving an Autologous Skin Graft.
Hsu CH , Rokni GR , Aghazadeh N , Brinster N , Li Y , Muehlenbachs A , Goldsmith CS , Zhao H , Petersen B , McCollum AM , Reynolds MG . J Infect Dis 2016 214 (8) 1171-4 We present a report of a burn patient who developed skin lesions on her skin-graft harvest and skin-graft recipient (burn) sites. Orf virus infection was confirmed by a combination of diagnostic assays, including molecular tests, immunohistochemistry, pathology and electron microscopy. DNA sequence analysis grouped this orf virus isolate among isolates from India. Though no definitive source of infection was determined from this case, this is the first reported case of orf virus infection in a skin graft harvest. Skin graft patients with exposures to animals may be at risk for this viral infection. |
The geography of malaria genetics in the Democratic Republic of Congo: A complex and fragmented landscape.
Carrel M , Patel J , Taylor SM , Janko M , Mwandagalirwa MK , Tshefu AK , Escalante AA , McCollum A , Alam MT , Udhayakumar V , Meshnick S , Emch M . Soc Sci Med 2014 133 233-41 Understanding how malaria parasites move between populations is important, particularly given the potential for malaria to be reintroduced into areas where it was previously eliminated. We examine the distribution of malaria genetics across seven sites within the Democratic Republic of Congo (DRC) and two nearby countries, Ghana and Kenya, in order to understand how the relatedness of malaria parasites varies across space, and whether there are barriers to the flow of malaria parasites within the DRC or across borders. Parasite DNA was retrieved from dried blood spots from 7 Demographic and Health Survey sample clusters in the DRC. Malaria genetic characteristics of parasites from Ghana and Kenya were also obtained. For each of 9 geographic sites (7 DRC, 1 Ghana and 1 Kenya), a pair-wise RST statistic was calculated, indicating the genetic distance between malaria parasites found in those locations. Mapping genetics across the spatial extent of the study area indicates a complex genetic landscape, where relatedness between two proximal sites may be relatively high (RST > 0.64) or low (RST < 0.05), and where distal sites also exhibit both high and low genetic similarity. Mantel's tests suggest that malaria genetics differ as geographic distances increase. Principal Coordinate Analysis suggests that genetically related samples are not co-located. Barrier analysis reveals no significant barriers to gene flow between locations. Malaria genetics in the DRC have a complex and fragmented landscape. Limited exchange of genes across space is reflected in greater genetic distance between malaria parasites isolated at greater geographic distances. There is, however, evidence for close genetic ties between distally located sample locations, indicating that movement of malaria parasites and flow of genes is being driven by factors other than distance decay. This research demonstrates the contributions that spatial disease ecology and landscape genetics can make to understanding the evolutionary dynamics of infectious diseases. |
Genetic variation and recurrent parasitaemia in Peruvian Plasmodium vivax populations.
McCollum AM , Soberon V , Salas CJ , Santolalla ML , Udhayakumar V , Escalante AA , Graf PC , Durand S , Cabezas C , Bacon DJ . Malar J 2014 13 (1) 67 BACKGROUND: Plasmodium vivax is a predominant species of malaria in parts of South America and there is increasing resistance to drugs to treat infections by P. vivax. The existence of latent hypnozoites further complicates the ability to classify recurrent infections as treatment failures due to relapse, recrudescence of hyponozoites or re-infections. Antigen loci are putatively under natural selection and may not be an optimal molecular marker to define parasite haplotypes in paired samples. Putatively neutral microsatellite loci, however, offer an assessment of neutral haplotypes. The objective here was to assess the utility of neutral microsatellite loci to reconcile cases of recurrent parasitaemia in Amazonian P. vivax populations in Peru. METHODS: Patient blood samples were collected from three locations in or around Iquitos in the Peruvian Amazon. Five putatively neutral microsatellite loci were characterized from 445 samples to ascertain the within and amongst population variation. A total of 30 day 0 and day of recurrent parasitaemia samples were characterized at microsatellite loci and five polymorphic antigen loci for haplotype classification. RESULTS: The genetic diversity at microsatellite loci was consistent with neutral levels of variation measured in other South American P. vivax populations. Results between antigen and microsatellite loci for the 30 day 0 and day of recurrent parasitaemia samples were the same for 80% of the pairs. The majority of non-concordant results were the result of differing alleles at microsatellite loci. This analysis estimates that 90% of the paired samples with the same microsatellite haplotype are unlikely to be due to a new infection. CONCLUSIONS: A population-level approach was used to yield a better estimate of the probability of a new infection versus relapse or recrudescence of homologous hypnozoites; hypnozoite activation was common for this cohort. Population studies are critical with the evaluation of genetic markers to assess P. vivax biology and epidemiology. The additional demonstration of microsatellite loci as neutral markers capable of distinguishing the origin of the recurrent parasites (new infection or originating from the patient) lends support to their use in assessment of treatment outcomes. |
Investigation of the first laboratory-acquired human cowpox virus infection in the United States.
McCollum AM , Austin C , Nawrocki J , Howland J , Pryde J , Vaid A , Holmes D , Weil MR , Li Y , Wilkins K , Zhao H , Smith SK , Karem K , Reynolds MG , Damon IK . J Infect Dis 2012 206 (1) 63-8 BACKGROUND: Cowpox virus is an Orthopoxvirus that can cause infections in humans and a variety of animals. Infections occur in Eurasia; human nor animal infection has been reported in the United States. This report describes the occurrence of the first known human case of laboratory-acquired cowpox virus infection in the United States and ensuing investigation. METHODS: The patient and laboratory personnel were interviewed, and laboratory activities were reviewed. Real-time PCR and serologic assays were used to test the patient's specimens. PCR assays were used to test specimens obtained during the investigation. RESULTS: The patient's lesion tested positive for cowpox virus DNA. Genome sequencing revealed a recombinant region consistent with a strain of cowpox virus stored in the research laboratory's freezer. Cowpox virus contamination was detected in six additional laboratory stocks of viruses. Orthopoxvirus DNA was present in three of twenty environmental swabs taken from laboratory surfaces. CONCLUSIONS: The handling of contaminated reagents or contact with contaminated surfaces was likely the mode of transmission. Delays in recognition and diagnosis of this infection in a laboratory researcher underscore the importance of a thorough patient history--including occupational information--and laboratory testing to facilitate a prompt investigation and application of control and remediation measures. |
South American Plasmodium falciparum after the malaria eradication era: clonal population expansion and survival of the fittest hybrids.
Griffing SM , Mixson-Hayden T , Sridaran S , Alam MT , McCollum AM , Cabezas C , Marquino Quezada W , Barnwell JW , Macedo De Oliveira A , Lucas C , Arrospide N , Escalante AA , Bacon DJ , Udhayakumar V . PLoS One 2011 6 (9) e23486 Malaria has reemerged in many regions where once it was nearly eliminated. Yet the source of these parasites, the process of repopulation, their population structure, and dynamics are ill defined. Peru was one of malaria eradication's successes, where Plasmodium falciparum was nearly eliminated for two decades. It reemerged in the 1990s. In the new era of malaria elimination, Peruvian P. falciparum is a model of malaria reinvasion. We investigated its population structure and drug resistance profiles. We hypothesized that only populations adapted to local ecological niches could expand and repopulate and originated as vestigial populations or recent introductions. We investigated the genetic structure (using microsatellites) and drug resistant genotypes of 220 parasites collected from patients immediately after peak epidemic expansion (1999-2000) from seven sites across the country. The majority of parasites could be grouped into five clonal lineages by networks and AMOVA. The distribution of clonal lineages and their drug sensitivity profiles suggested geographic structure. In 2001, artesunate combination therapy was introduced in Peru. We tested 62 parasites collected in 2006-2007 for changes in genetic structure. Clonal lineages had recombined under selection for the fittest parasites. Our findings illustrate that local adaptations in the post-eradication era have contributed to clonal lineage expansion. Within the shifting confluence of drug policy and malaria incidence, populations continue to evolve through genetic outcrossing influenced by antimalarial selection pressure. Understanding the population substructure of P. falciparum has implications for vaccine, drug, and epidemiologic studies, including monitoring malaria during and after the elimination phase. |
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